Academic Press is an imprint of Elsevier 525 B Street, Suite 1900, San Diego, CA 92101-4495, USA 30 Corporate Drive, Suite 400, Burlington, MA 01803, USA 32, Jamestown Road, London NW1 7BY, UK First edition 2008 Copyright # 2008 Elsevier Inc. All rights reserved No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means electronic, mechanical, photocopying, recording or otherwise without the prior written permission of the publisher Permissions may be sought directly from Elsevier’s Science & Technology Rights Department in Oxford, UK: phone (+44) (0) 1865 843830; fax (+44) (0) 1865 853333; email:
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CONTRIBUTORS
Stephen J. W. Busby School of Biosciences, University of Birmingham, Edgbaston, Birmingham B15 2TT, United Kingdom. Jennifer S. Cavet Life Sciences, University of Manchester, Manchester, M13 9PT, United Kingdom. Christopher Y. Choi Department of Agricultural and Biosystems Engineering, University of Arizona, Tucson, Arizona 85721. Nicholas Clipson Environmental Microbiology Group, School of Biology and Environmental Science, University College Dublin, Ardmore House, Belfield, Dublin 4, Ireland. David Corbett Faculty of Life Sciences, University of Manchester, Manchester, UK. Evelyn Doyle Environmental Microbiology Group, School of Biology and Environmental Science, University College Dublin, Ardmore House, Belfield, Dublin 4, Ireland. Cormac GM Gahan Alimentary Pharmabiotic Centre, Department of Microbiology and School of Pharmacy, University College Cork, Cork, Ireland. Charles P. Gerba Department of Soil, Water and Environmental Science, University of Arizona, Tucson, Arizona 85721. David C. Grainger Department of Biological Sciences, University of Warwick, Coventry CV4 7AL, UK. Anne Marie Hickey Environmental Microbiology Group, School of Biology and Environmental Science, University College Dublin, Ardmore House, Belfield, Dublin 4, Ireland.
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Contributors
Colin Hill Department of Microbiology and Alimentary Pharmabiotic Centre, University College Cork, Cork, Ireland. Kimon A. G. Karatzas Department of Microbiology, School of Natural Sciences, National University of Ireland Galway, Galway, Ireland. Donald Y. Kobayashi Department of Plant Biology and Pathology, Rutgers University, New Brunswick, New Jersey, 08902. Chin Hong Ma Division of Biological Sciences, University of California at San Diego, La Jolla, California 92093-0116. Lorraine Muckian Environmental Microbiology Group, School of Biology and Environmental Science, University College Dublin, Ardmore House, Belfield, Dublin 4, Ireland. Conor P. O’Byrne Department of Microbiology, School of Natural Sciences, National University of Ireland Galway, Galway, Ireland. Deenah Osman Life Sciences, University of Manchester, Manchester, United Kingdom. Cynthia A. Pielach Department of Plant Biology and Pathology, Rutgers University, New Brunswick, New Jersey, 08902. Mark R. Riley Department of Agricultural and Biosystems Engineering, University of Arizona, Tucson, Arizona 85721. Daniel P. Roberts Sustainable Agricultural Systems Laboratory, USDA-Agricultural Research Service, Henry A. Wallace Beltsville Agricultural Research Center, Beltsville, Maryland, 20705-2350. Ian S. Roberts Faculty of Life Sciences, University of Manchester, Manchester, M13 9PT, UK. Loren Rodgers Division of Biological Sciences, University of California at San Diego, La Jolla, California 92093-0116.
Contributors
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Sheila Ryan Department of Microbiology, University College Cork, Cork, Ireland. Milton H. Saier Division of Biological Sciences, University of California at San Diego, La Jolla, California 92093-0116. Ryan G. Sinclair Department of Soil, Water and Environmental Science, University of Arizona, Tucson, Arizona 85721. Dorjee G. Tamang Division of Biological Sciences, University of California at San Diego, La Jolla, California 92093-0116. Ming Ren Yen Division of Biological Sciences, University of California at San Diego, La Jolla, California 92093-0116.
CHAPTER
1 Capsular Polysaccharides in Escherichia coli David Corbett and Ian S. Roberts1
Contents
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I. II. III. IV. V. VI. VII.
Introduction Functions of Bacterial Capsules Capsular Polysaccharides in E. coli E. coli Group I Capsules E. coli Group 4 Capsules E. coli Group 3 Capsules E. coli Group 2 capsules A. Genetics and evolution of E. coli Group 2 capsules B. Biosynthesis of E. coli Group 2 capsular polysaccharides VIII. Export of E. coli Group 2 Polysaccharides A. Group 2 capsular polysaccharide synthesis and export are linked IX. Regulation of Capsule Expression in E. coli A. Regulation of the E. coli K30 capsule and expression of colanic acid (Slime) in E. coli K-12 strains B. Regulation of expression of Group 2 (K5) capsule gene clusters X. Conclusions References
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Faculty of Life Sciences, University of Manchester, Manchester, UK Corresponding author: Faculty of Life Sciences, University of Manchester, Manchester, M13 9PT, UK
Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00601-1
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2008 Elsevier Inc. All rights reserved.
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I. INTRODUCTION The expression of extracellular polysaccharide (EPS) material is a common feature of many bacteria. This EPS coats the outside of the bacterial cell and as a consequence plays an intimate role in mediating interactions between the bacterium and its immediate environment. In certain cases the polysaccharide may be tightly associated with the cell surface forming a discrete structure termed a capsule, or it may be shed in the form of EPS or slime. A number of roles have been assigned to polysaccharide capsules and it is clear that in a variety of environments the expression of a capsule confers a selective advantage to the host. The major components of bacterial capsules are highly hydrated, high molecular weight acidic polysaccharides that confer upon bacteria an overall negative charge and hydrophilic properties. There is great structural diversity in capsular polysaccharides both between different bacterial species but also within the same bacterial species. This diversity is a consequence of not only differences in the repeat monosaccharide components but also differences in linkage between the different repeating monosaccharide units. The selective pressure that has driven this diversity is unclear as are the mechanisms by which it has been achieved. However, a consequence of this structural diversity is that there exists a library of diverse polysaccharide structures within the microbiome that may be exploited to engineer novel polysaccharide molecules with particular biochemical, pharmacological, or immunological properties.
II. FUNCTIONS OF BACTERIAL CAPSULES A number of functions have been assigned to bacterial capsules in different bacteria including adhesion, transmission, resistance to innate host defenses, resistance to the host’s adaptive immune response, and intracellular survival (Roberts, 1996). In certain cases it is possible to directly correlate the function of the bacterial capsule with the chemical structure of the capsular polysaccharide. For instance, the adhesion of Group A Streptococci to pharyngeal cells mediated via the interaction between the hyaluoronic acid capsule and CD44, the hyaluronic acid binding protein (Cywes and Wessels, 2001). In the case of invasive pathogens an ability to survive innate host defenses is essential. It has been known for a long time that the expression of a polysaccharide capsule confers some measure of resistance to complement-mediated killing (Roberts, 1996) even though mechanistically the basis for this is not always clear. In the case of capsules that contain sialic acid, binding of factor H and the inhibition of the complement activation cascade can explain this resistance, but with
Capsular Polysaccharides in Escherichia coli
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other capsules it may be due to steric effects and masking the cell surface form the membrane-attack complex. What is clear is that complement mediated resistance is likely to involve a number of cell surface structures which contribute to the overall effect (Burns and Hull, 1998, 1999). The ability of capsules to confer resistance to phagocytosis by polymorphonuclear (PMNL) cells has long been assigned to the negatively charged polysaccharide capsule and the repulsive effect on the negatively charged cell surface of the PMNL (Roberts, 1996). However, it is likely that poor opsonization with complement of encapsulated bacteria will also play a role in this protection (Roberts, 1996). The Escherichia coli K1 capsule is vital for intracellular survival and crossing the blood brain barrier (Kim et al., 2003). Specifically, the K1 capsule moderates the maturation process of E. coli containing vacuoles inside endothelial cells preventing fusion with lysosomes (Kim et al., 2003). As such, expression of the K1 capsule is critical to the pathology of the disease.
III. CAPSULAR POLYSACCHARIDES IN E. coli E. coli is a facultatively anaerobic, Gram-negative bacillus that forms part of the commensal human bowel flora, but in the environment can be found in soil and water, usually as the result of fecal contamination. Although considered a commensal organism and widely used as a workhorse in molecular biology research, E. coli is capable of causing a range of diseases in humans and animals, including gastro-intestinal and urinary tract infections, meningitis, and septicemia. A common feature of E. coli isolates responsible for extraintestinal infections is the expression of a polysaccharide capsule or K antigen. The expression of certain K antigens is strongly associated with particular infections. For example, the K1 capsule is the most common capsule type found in isolates of E. coli causing neonatal meningitis and urinary tract infection. The K5 polysaccharide is associated both with urinary tract infection and sepsis, but not with meningitis. In both cases, these capsules are more often found associated with infection than in the normal intestinal flora of healthy individuals (Kaijser and Jodal, 1984). There are more than 80 different K antigens in E. coli, and originally, they were divided into Groups I and II on the basis of serological, biosynthetic and genetic data (Jann and Jann, 1997). The system has since been restructured to take account solely of biochemical and genetic data, comprising four groups: Group 1 (Ia), Group 2 (II), Group 3 (III), and Group 4 (Ib) (Whitfield and Roberts, 1999). The following sections briefly consider the genetics, biosynthesis and evolution of the capsular polysaccharides of the related Groups 1 and 4, then Group 3, followed by a detailed analysis of the Group 2 capsular polysaccharides.
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IV. E. coli GROUP I CAPSULES Group 1 capsules, encoded by the cps locus located near his, are typified by E. coli K30, which is a polymer of galactose, mannose, and glucuronic acid. They are similar to those expressed by Klebsiella strains, although in E. coli the capsular polysaccharide is expressed in two forms. The first comprises one to several repeat units of the K polysaccharide linked to lipid A-core, and is termed KLPS (Dodgson et al., 1996). This is not synthesized by Klebsiella spp. (Whitfield and Roberts, 1999). Lipid A and core are two conserved constituent domains of LPS, the third being the highly variable O antigen. All three components are synthesized separately and ligated together later. Lipid A is formed from UDP-GlcNAc and fatty acids that are transferred to a Kdo disaccharide. The core is an oligosaccharide linker that is formed on lipid A by the sequential transfer of glucose, galactose, and GlcNAc from their nucleotide precursors. The second higher molecular weight polysaccharide forms the capsule proper. In each case the repeating unit of the polysaccharide is identical. The Group 1 capsule biosynthetic locus is a 16 kb region of DNA encoding 12 ORFs located in the same region of DNA as the typical O antigen biosynthetic locus in E. coli K-12 and strains bearing capsules from Group 2, 3, or 4 (Drummelsmith and Whitfield, 1999; Rahn et al., 1999). The Group 1 gene cluster is distinguished by the presence of an essential polymerization and translocation region dedicated to capsule expression (wzi–wzc) that is conserved between different strains of E. coli expressing Group 1 capsules and K. pneumoniae (Whitfield, 2006). Strains bearing Group 1 capsules are unable to co-express colanic acid, the first evidence for which emerged when it was found that multicopy RcsB in E. coli K30, K1, K5, and K-12 resulted in a mucoid phenotype at 37 C, but only in serotype K30 was mucoidy the result of serotype-specific capsular polysaccharide expression: in all of the other strains this was due to colanic acid expression (Drummelsmith and Whitfield, 1999; Keenleyside et al., 1992). Unlike bacteria belonging to Groups 2, 3, and 4, the genes responsible for synthesis of this EPS have been lost from Group 1 strains, probably through extensive DNA re-arrangements involving replacement of the O-antigen synthesis region by a large segment of DNA laterally transferred from K. pneumoniae (Rahn et al., 1999; Whitfield, 2006). It is not known how Group 1 capsules are linked to the bacterial cell surface, but unlike KLPS, it does not involve LPS (Whitfield, 2006). The repeat units of these capsules are formed on the cytoplasmic face of the bacterial inner membrane followed by export across the inner membrane and polymerization to form the capsular polysaccharide. The precursor monosaccharides are first synthesized by the appropriate enzymes (e.g., ManB and ManC are responsible for generating UDP-mannose).
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The glycosyltransferase enzyme WbaP then transfers galactose from free UDP-galactose in the cytoplasm to undecaprenyl phosphate, a lipid carrier molecule (Drummelsmith and Whitfield, 1999; Roberts, 1996). A further glycosyl transferase, namely WbaZ, then completes the formation of the repeating unit backbone, -2)-a-Man-(1–3)-b-Gal-(1-. A sidebranch also exists, formed from repeating glucuronic acid and galactose residues by the glycosyltransferase WcaN, which is linked to the main polysaccharide chain by WcaO (Drummelsmith and Whitfield, 1999). The repeat units are flipped across the bacterial inner membrane by an unknown process involving Wzx before being attached to the reducing terminus of the nascent undecaprenyl phosphate-linked polysaccharide at its reducing terminus by Wzy on the periplasmic face of the inner membrane. The Wzy protein is believed to function as a polymerase, although this role has not been directly demonstrated (Whitfield, 2006). Mutations in Wzy abolish capsule expression and reduce the length of KLPS to one repeat unit (Drummelsmith and Whitfield, 1999). At some point the length of the nascent polymer must trigger export, and either Wzy or WaaL may play a role in determining the chain length (Whitfield, 2006). Strains carrying mutations in wzy are acapsular and add only one repeat unit onto KLPS (Drummelsmith and Whitfield, 1999). Polymerization is terminated for KLPS by WaaL-mediated transfer of the polymer to lipid A-core. Translocation of the finished polymer involves the products of the genes wza, wzb, and wzc, encoded within a polymerization and translocation locus located upstream of the serotype-specific biosynthetic loci. Wzi (formerly orf3 or orfX) is not essential for capsule expression (Drummelsmith and Whitfield, 1999), but wzi mutants show a significant reduction in cell associated and cell-free polymer (Rahn et al., 2003). Wza is a surface-exposed outer membrane lipoprotein that forms octameric structures in the outer membrane, the bulk of which are exposed in the periplasm, and is essential for surface presentation of capsule (Collins et al., 2007; Dong et al., 2006; Drummelsmith and Whitfield, 2000; Nesper et al., 2003). It represents the outer membrane accessory (OMA) protein of Group 1 capsules. OMAs carry a conserved signal peptidase motif that, after cleavage, is modified at a conserved cysteine residue to yield a lipoprotein (Paulsen et al., 1997). Failure to acetylate Wza results in a failure of capsule export and intracellular accumulation of capsule polymer (Nesper et al., 2003). Wza is found associated with Wzc, interacting via their periplasmic domains (Collins et al., 2007). Wza-Wzc interaction is believed to hold Wza in an open conformation conducive to capsule ˚ export, as the Wza octomer encloses a large central cavity with a 22A pore (Collins et al., 2007). However, in the absence of Wzc, the Wza ring is closed at both the periplasmic and external faces (Beis et al., 2004; Dong et al., 2006). Wzc is a tyrosine autokinase protein similar to the chainlength regulating protein Wzz found in strains from other capsule groups.
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Wzc differs however, by an extension at its C-terminus containing walker A and B box motifs and a tyrosine-rich region (Collins et al., 2007; Nesper et al., 2003; Wugeditsch et al., 2001), and as such is a representative of the MPA-1 family of cytoplasmic membrane-periplasm auxiliary proteins (Paulsen et al., 1997). At least four of these tyrosine residues must be phosphorylated for function, although no individual residue is essential (Paiment et al., 2002; Wugeditsch et al., 2001). Wzb is a protein tyrosine phosphatase that dephosphorylates Wzc. Both wzb and wzc mutants result in an acapsular phenotype, so it is likely that a cycle of phosphorylation and dephosphorylation is important in properly regulating capsule expression. Additionally, multicopy wzb causes a near four-fold reduction in capsule production (Paiment et al., 2002; Whitfield, 2006).
V. E. coli GROUP 4 CAPSULES Group 4 capsules are found in enteropathogenic (EPEC) and some enterotoxigenic (ETEC) E. coli, but similar capsule types are not known to exist in other bacteria (Peleg et al., 2005; Whitfield, 2006). Members of this group are alternatively known as O-antigen capsules as they are very similar to LPS, with up to 50% of the capsule polymer expressed by these strains linked to lipid A-core (Dodgson et al., 1996; Roberts, 1996). LPS normally consists of a lipid A-core moiety linked to an O polysaccharide. These bacteria are said to possess smooth LPS. Mutants that fail to produce the O-specific polysaccharide and thus display only lipid A and the core oligosaccharide are termed rough mutants and are virtually avirulent. The capsular O antigens, e.g., K40, are able to mask co-expressed O8/O9 antigen in serological analyses in a similar manner to other K antigen capsules, hence them originally being given a K antigen designation (Whitfield and Roberts, 1999). Unlike strains bearing Group 1 capsules, the colanic acid locus of Group 4 strains is intact, and colanic acid can be co-expressed with the capsular polysaccharide (Whitfield, 2006). Biosynthesis of the Group 4 capsular antigen occurs in the same manner as described for Group 1 capsules except that the initiating glycosyltransferase enzyme is Wca, transferring GlcNAc or N-acetyl galactose (GalNAc), not WbaP (Whitfield and Roberts, 1999). The mechanism by which Group 4 capsules are transported involves homologues of the Group 1 transport genes Wza, Wzb (Etp), and Wzc (Etk) located at 22 minutes on the E. coli chromosome (Peleg et al., 2005). Wza at this locus is also able to function, albeit modestly, in the export of Group 1 capsules (Drummelsmith and Whitfield, 2000; Wugeditsch et al., 2001). Four additional genes that form part of the same operon (ymcABCD) are all essential for capsule expression, although their function is unknown (Peleg et al., 2005).
Capsular Polysaccharides in Escherichia coli
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Unlike the capsule, the polysaccharide chain length of KLPS is under the control of the enzyme Wzz in strains with Group 4 capsules. Wzz is absent from Group 1 strains, which explains why Group 1 KLPS bears only low molecular weight polysaccharides. In the absence of Wzz, KLPS chain length is uncontrolled, usually resulting in shorter oligosaccharide chains. Polymer extension is terminated by transfer of the nascent polymer to the lipid A-core acceptor molecule by the enzyme WaaL (Whitfield and Roberts, 1999).
VI. E. coli GROUP 3 CAPSULES Prime examples of this group of E. coli capsular polysaccharides include the K10 and K54 antigens, formerly assigned to Group III (Clarke et al., 1999; Russo et al., 1998). Gene clusters and capsules of Group 3 show similarities to those of Group 2 in terms of their lack of thermostability, possession of homologues to the Group 2 biosynthetic genes KpsM, T, C, and S—the latter two of which are functionally interchangeable between the two groups—and similarity to the capsules of N. meningitidis and H. influenzae (Pearce and Roberts, 1995; Whitfield and Roberts, 1999). Unlike Group 2 capsule gene clusters, those of Group 3 are not thermo-regulated, and the cluster shares little sequence identity with the Group 2 genes (Whitfield, 2006). The Group 3 cluster is significantly re-arranged compared to Group 2 clusters, being located downstream of a truncated kpsM gene homologous to that found in Group 2 (Russo et al., 1998). This is followed by region 1 containing kpsD, kpsM, kpsT, and kpsE, the region 2 biosynthetic genes, and a third region composed of kpsC and kpsS. A remnant of IS110 from Streptomyces coelicolor is located immediately downstream of the cryptic kpsM in both K54 and K10, and in K10 there is an IS3 element upstream of the cryptic kpsM (Clarke et al., 1999; Russo et al., 1998) and a prophage-like element downstream of the capsule gene cluster. It has been suggested that the similarity between the truncated kpsM gene and kpsM of Group 2 capsules indicates that Group 3 strains are descended from a Group 2 progenitor that has acquired a new capsule gene cluster through horizontal transfer. The presence of several IS sequences in these clusters may provide clues to the evolution of the Group 3 capsules (Clarke et al., 1999; Russo et al., 1998).
VII. E. coli GROUP 2 CAPSULES Group 2 capsules are expressed by many extraintestinal isolates of E. coli, and closely resemble those found in N. meningitidis and H. influenzae (Frosch et al., 1991). Capsular polysaccharides of this group are linked
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via their reducing termini to phosphatidyl-Kdo, which may play a role in anchoring the capsular polysaccharide to the cell surface (Finke et al., 1991). Group 2 capsules are distinguished by their temperature-regulated nature, being expressed at 37 C, but not below 20 C, and this control of expression has been shown to be transcriptional in nature (Rowe et al., 2000; Simpson et al., 1996). The differential expression allows for selective expression of the capsule when bacteria encounter a host, and newly synthesized capsule appears within 25–30 min of a temperature upshift (Jann and Jann, 1997).
A. Genetics and evolution of E. coli Group 2 capsules Group 2 capsule gene clusters are organized into three principal regions. Regions 1 and 3 contain the genes responsible for transport of newly synthesized capsular polysaccharide from the cytoplasm to the bacterial cell surface, and are conserved in all Group 2 capsule gene clusters. Region 2 encodes the genes responsible for the synthesis of the polysaccharide and its precursors (Fig. 1.1) (Whitfield, 2006). Region 1 comprises a single transcriptional unit containing six genes, kpsFEDUCS. There is a s70 promoter (PR1) located 225 bp upstream of kpsF (Simpson et al., 1996). No alternative sigma factor recognition sites are present in this promoter, although it does harbour a binding site for the DNA architectural protein, integration host factor (IHF) (Rowe et al., 2000). Transcription from PR1 generates an 8 kb polycistronic message that is later processed to yield a separate 1.3 kb kpsS-specific transcript, and this processing has been proposed to play a role in the differential expression of this gene
RNaseE/III?
PR1
kps
PR3
F
E
D U
C
T
S kfi
D
C
B
M
A
Conserved in all Group 2 capsule gene clusters.
FIGURE 1.1 Genetic organization and transcription pattern of the E. coli K5 capsule gene cluster. The kps genes are conserved in all Group 2 capsule gene clusters and encode the proteins for polysaccharide export. The kfi genes are K5-specific and would be replaced by other capsule specific genes in different K antigen expressing E. coli. The two major promoters are shown as PR1 and PR3 and the arrows denote the detected transcripts at 37 C. The mechanism by which the kpsS-specific transcript is generated is unclear.
Capsular Polysaccharides in Escherichia coli
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(Fig. 1.1) (Roberts, 2000). The kpsF gene contains a Rho-dependent transcriptional terminator. Rho is an RNA-binding protein that exists as a hexamer, requiring a particular DNA sequence –CACA(Y)3 and C(N)3CC, also known as rut—approximately 200 bp upstream of the termination site (Ciampi, 2006). The Rho protein is proposed to track behind RNA polymerase as it proceeds through transcription. If RNA polymerase pauses, transcription is terminated when the Rho protein catches up (Ciampi, 2006). These intragenic terminators are believed to play a role in reducing unnecessary transcription during times of physiological stress. Region 3 contains two genes, kpsMT, which are involved in transport of the capsular polysaccharide across the cytoplasmic membrane (Fig. 1.1) (Bliss and Silver, 1996). The region 3 promoter (PR3) is located 741 bp upstream of the first of the two genes in region 3, kpsM. Transcription from this promoter is driven through region 2, past a Rho-dependent transcriptional terminator that exists between kpsT and kfiA, the first gene of region 2. Unlike regions 1 and 3, region 2 is serotype-specific (Roberts, 1996). In the K5 gene cluster, this region consists of kfiA, kfiB, kfiC, and kfiD. A fifth ORF was identified, although expression of the predicted 16 kDa gene product could not be demonstrated (Fig. 1.1) (Petit et al., 1995). In serotype K1, region 2 consists of six genes, neuDBACES (Whitfield, 2006). Region 2 of the K5 capsule gene cluster has a higher AþT content (66%) than either region 1 or 3 which possess 50% and 57% AT respectively, values more typical for the E. coli chromosome (Blattner et al., 1997; Petit et al., 1995). This suggests that region 2 has evolved through the acquisition of capsule gene DNA sequences from other bacteria. It is not known precisely how this has happened, but it is believed that homologous recombination events between regions 1 and 3 of incoming and resident capsule DNA clusters may account for this (Roberts, 1996). Such en bloc acquisition of biosynthetic loci is supported by the fact that the C-terminal regions of kpsS (region 1) and kpsT (region 3) from K1 and K5 which flank, and therefore form junctions with, region 2 harbor the greatest divergence in sequence of the conserved regions (Boulnois and Jann, 1989; Pavelka et al., 1994; Petit et al., 1995; Roberts, 1996). Additionally, it has been suggested that kfiD might have been acquired from a Streptococcal species (Munoz et al., 1998). Relatively long intergenic regions exist in region 2: kfiA and kfiB are separated by 340 bp, and kfiB is separated from kfiC by 1293 bp (Petit et al., 1995). The purpose of these regions has not been determined, although three promoters have been identified in region 2, each upstream of kfiA, kfiB, and kfiC, generating 8, 6, and 3.5 kb transcripts, respectively. These promoters are relatively weak (Petit et al., 1995), and are probably insufficient for levels of the biosynthetic proteins necessary to express a K5 capsule (Stevens et al., 1997). Instead, the vast majority of region
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2 message is produced by read-through transcription from PR3, generating a polycistronic transcript containing both the regions 3 and 2 genes (Stevens et al., 1997).
B. Biosynthesis of E. coli Group 2 capsular polysaccharides Synthesis of Group 2 capsular polysaccharides occurs on the inner face of the cytoplasmic membrane (Roberts, 1996). The current model for capsule synthesis is one that is linked to polysaccharide export via a heterooligomeric synthesis-export complex of the region 2 proteins KfiABC and D bound to the bacterial inner membrane together with the Kps export proteins which span the periplasm and outer membrane (Fig. 1.2) (McNulty et al., 2006; Rigg et al., 1998; Whitfield, 2006). In serotype K1, the polysialic acid capsule is synthesized from activated UDP-NeuNAc acid produced from N-acetylmannosamine (ManNAc)
KpsF KpsU KfiD KfiC KfiB KfiA UDP-Glc UDP-GlcA/GlcA UDP-GlcNAc/GlcNAc Membrane acceptor KpsC
Outer membrane Periplasm
D
KpsS Kdo
Inner membrane
KpsT KpsM B KpsE
A Ru5P
ATP ADP
ATP ADP
C
A5P
KpsD
FIGURE 1.2 Synthesis and export of the K5 capsular polysaccharide. Synthesis of the K5 polysaccharide occurs on the inner face of the cytoplasmic membrane (A) by successive transfer of GlcA and GlcNAc residues at the nonreducing end of the nascent polysaccharide by KfiC and KfiA. KpsF converts ribulose 5-phosphate (Ru5P) to arabinose 5-phosphate (A5P), which is an intermediate in the production of CMP-Kdo by KpsU (B) KpsS and KpsC are believed to play a role in the transfer of Kdo to the reducing terminus of the finished polysaccharide, and initiation of polymer export. Transport across the cytoplasmic membrane is achieved by KpsM and KpsT (C), whilst transport to the cell surface requires KpsE and KpsD (D). (See Color Plate Section in the back of the book.)
Capsular Polysaccharides in Escherichia coli
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and phosphoenolpyruvate (Bliss and Silver, 1996). Neither lipid cofactors nor lipid-linked intermediates (e.g., undecaprenyl phosphate) are required for K5 polysaccharide synthesis, but a polyisoprenoid lipid intermediate is used in K1 synthesis (Bliss and Silver, 1996). The initiating sugar, and its acceptor molecule upon which the polymerization reaction occurs, have not been confirmed (Jann and Jann, 1997), although recent observations have suggested that initiation involves the attachment of GlcNAc to an unidentified membrane acceptor in K5 (Roman et al., 2003). Synthesis of the K5 polysaccharide occurs via the step-wise addition of alternating GlcA and GlcNAc residues from their nucleoside-sugar precursors to the nonreducing end of the polysaccharide (Fig. 1.2). KfiA is an a-UDP-GlcNAc glycosyltransferase enzyme whose function is to catalyze the addition of GlcNAc to the nonreducing terminus of a nascent K5 polysaccharide chain via an a-1,4-glycosidic bond (Hodson et al., 2000; Roman et al., 2003). Glycosyltransferase enzymes function by two main mechanisms, namely retention or inversion of the a- or b-configuration of the anomeric carbon atom on the sugar substrate, depending on whether an a- or b-linked product is to be formed. In this case, it is presumed that KfiA retains the a-configuration of the donor sugar (Saxena et al., 1995). The role of KfiB has not as yet been elucidated, but it may be a structural one, supporting the biosynthetic complex: mutation of kfiB, as with the other genes of region 2, abolishes K5 capsule expression (Hodson et al., 2000). KfiD is the enzyme responsible for dehydrogenation of UDP-glucose, itself formed from glucose-6-phosphate, to form UDP-GlcA, a key substrate for the K5 polysaccharide, but one which is not otherwise required by E. coli K5 (Roman et al., 2003; Sieberth et al., 1995). Overexpression of KfiD reduces the amount of K5 polysaccharide produced, possibly because the increased production of UDP-glucose reduces intracellular stocks of glucose-6-phosphate. This molecule exists in equilibrium with fructose-6-phosphate, the precursor of UDP-GlcNAc, and so the reduction of the precursor could lead to stalling of initiation and/or polymerization of the capsule polysaccharide at the point of GlcNAc addition (Roman et al., 2003). Catalysis of the addition of UDP-GlcA to the nascent polysaccharide is the responsibility of the b-UDP-GlcA b-glycosyltransferase enzyme, KfiC (Griffiths et al., 1998). The kfi gene products are also structurally important for the synthesis-export complex, as targeting of KfiA to the cytoplasmic membrane requires KfiC, targeting of KfiC requires both KfiA and KfiB, and targeting of KfiB requires KfiA and KfiC (Hodson et al., 2000). KpsF, the product of the first gene in region 1, catalyzes the conversion of ribulose 5-phosphate to arabinose 5-phosphate, an intermediate in Kdo synthesis (Meredith and Woodard, 2006; Tzeng et al., 2002). The capsule gene clusters of N. meningitidis lack kpsF homologues, thus explaining the defects that these bacteria suffer in capsule and LOS expression when the kpsF homologue located elsewhere
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on the chromosome is mutated (Tzeng et al., 2002). Nonpolar mutations in kpsF reduce surface presentation of capsule 10-fold in E. coli K1, with a concomitant intracellular accumulation of capsular polysaccharide (Cieslewicz and Vimr, 1997), although it is unclear why this should be given that Kdo has no known role in K1 expression. KpsF is not required for expression of the K5 capsule (Simpson et al., 1996), probably due to the presence of the kpsF homologue ybrH (but not gutQ) located elsewhere on the chromosome (Simpson et al., 1996; Tzeng et al., 2002). Similar accumulation of polysaccharide is not observed in N. meningitidis, whose kpsF mutants can be complemented by K1 kpsF (Tzeng et al., 2002). At 37 C, strains bearing Group 2 capsules display increased CMPKdo synthetase activity when compared to growth at 20 C, and to other E. coli serotypes. This is due to up-regulation of kpsU, the enzyme responsible for formation of CMP-Kdo, a precursor in the attachment of Kdo to phospholipid (Rosenow et al., 1995b). As with KpsF, KpsU is not essential for capsule expression as a homologue, kdsB, is encoded elsewhere on the chromosome (Roberts, 1996). The KpsC and KpsS proteins are able to associate with the inner membrane in the absence of other capsule proteins (Rigg et al., 1998), and believed, on the basis of similarity with the LipA and LipB proteins of Meningococci, to be responsible for the attachment of phosphatidyl-Kdo to the reducing terminus of the finished capsular polysaccharide immediately before export (Arrecubieta et al., 2001; Jann and Jann, 1997; Rigg et al., 1998). In addition to this, they play a vital role in stabilising the proposed capsule synthesis complex on the bacterial inner membrane, as KpsC and KpsS (in addition to KpsM and KpsT) are required for the targeting of KfiA and KfiC to the inner membrane (Rigg et al., 1998). A recent study with E. coli K1 has suggested that KpsC forms part of a minimal set of proteins, including NeuE and NeuS, required for de novo synthesis of polysialic acid in vitro and in vivo (Andreishcheva and Vann, 2006). Polymerization is dependent on KpsC, suggesting a role for it in initiation of capsule biosynthesis. In the same study, KpsS was shown to increase the yield of capsule polymer by an unknown mechanism (Andreishcheva and Vann, 2006).
VIII. EXPORT OF E. coli GROUP 2 POLYSACCHARIDES Translocation of capsular polysaccharides is a significant problem for bacteria due to their very high molecular weight and negative charge, and the fact that it must be moved across both the inner and outer membranes via the periplasm. Transfer across the cytoplasmic membrane is achieved by KpsM and KpsT, whereas KpsD and KpsE are responsible for transport across the periplasm (Fig. 1.2). The capsule export pathway does not recognize a specific motif in the structure of the capsular
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polysaccharide that would enable it to be transported out of the cell. The K5 region 3 genes can complement loss of function in K1 capsular genes, and capsule expression in hybrid systems combining components of the Actinobacillus pleuropneumonia and E. coli export pathways has been demonstrated (Roberts, 1996; Silver et al., 2001). KpsM and KpsT form an ATP-binding cassette type 2 (ABC-2) transporter. KpsM has at least six transmembrane domains and a total of five loops. Three of the loops are located in the periplasm and two in the cytoplasm. One model proposes that two molecules of KpsM form a pore in the inner membrane. A molecule of KpsT, which contains an ATP-binding domain, is bound to each KpsM molecule, whilst simultaneously being associated with the inner membrane. This complex functions to hydrolyze ATP to provide energy for transport of the polysaccharide. Due to the presence of homologues of KpsM and KpsT, a similar mechanism is proposed to exist in H. influenzae and N. meningitidis (Rigg et al., 1998; Roberts, 1996). Bliss and Silver (1996) proposed a co-insertional model for the function of KpsM and T. Both proteins are required for the initiation of polysaccharide export, and this relies on the interaction of KpsT with the polysaccharide (possibly mediated through KpsC or KpsS), ATP and KpsM. The interaction of the conserved KpsT with various polysaccharide structures is achieved through the recognition of the reducing-terminal phospholipid moiety. Binding of ATP to KpsT results in a conformational change in the protein leading to the insertion of KpsT into the inner membrane, whilst KpsM forms a pore around it. Following this, the bound ATP is hydrolyzed, removing the KpsM/T complex from the membrane and releasing the polysaccharide into the periplasm (Nsahlai and Silver, 2003; Pigeon and Silver, 1997; Silver et al., 2001). KpsE and KpsD mutants accumulate K5 polymer in the periplasm, confirming their role in transportation of the capsular polysaccharide across the periplasm (Bronner et al., 1993). Typically, ABC-2 transporters act in conjunction with MPA-2 proteins, forming a physical linkage between an ABC-2 transporter and an outer membrane porin, of which KpsE is an example (Paulsen et al., 1997). KpsE possesses an N-terminal transmembrane domain followed by a large periplasmic domain and a C-terminus that is exposed in the periplasm and also associated with the inner membrane (Arrecubieta et al., 2001; Rosenow et al., 1995a). KpsE has been shown to exist as a dimer by chemical cross-linking experiments (Arrecubieta et al., 2001). Translocation of the finished capsular polysaccharide has been suggested to be dependent on an unlinked porin in a similar manner to haemolysin A in E. coli which utilizes the unlinked tolC gene for export (Schlor et al., 1997; Thanabalu et al., 1998). This is because the kps gene cluster lacks an apparent OMA protein, which is typically required to complete the transport process started by KpsM and KpsT (Silver et al., 2001; Whitfield and Roberts, 1999). KpsD shows only limited
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similarity to OMAs such as Wza, and is not a lipoprotein (Arrecubieta et al., 2001; Whitfield, 2006), whereas the capsule gene clusters of H. influenzae and N. meningitidis both possess OMAs (bexD and ctrA respectively) (Whitfield and Roberts, 1999). Support for the porin theory stems from the observation that over-expression of KpsD in E. coli K-12 is lethal—if the hypothesized role was correct, this over-expression would recruit too many porins to the outer membrane, resulting in disruption of the cell’s osmotic balance (Bliss and Silver, 1996). If porins are involved, it is not known how the polysaccharides would be transported through the relatively small pores that they generate (Whitfield and Roberts, 1999). OmpT, LamB, OmpF, OmpA, and OmpC, have all been ruled out as candidates in this role (Arrecubieta et al., 2001). Detection of KpsD in both the cytoplasmic and outer membranes lead to the hypothesis that KpsD might assist capsule export in a manner that involves cycling of the protein between both membranes whilst chaperoning the polysaccharide to an outer membrane transport protein (Arrecubieta et al., 2001). In the presence of KpsE, Lpp, and the K5 polysaccharide, KpsD is exposed on the cell surface, anchored in the outer membrane by its N-terminus and has a large C-terminal domain exposed in the periplasm (Arrecubieta et al., 2001; McNulty et al., 2006). However, whether or not KpsD is directly involved in K5 export remains unclear, because it does not form heat stable oligomers in the way that OMAs such as Wza do, and has not yet been shown to form pores in lipid bilayers in vitro (McNulty et al., 2006). The RhsA protein was identified as being necessary for maximal levels of K5 biosynthesis, but does not affect transcription of the biosynthetic genes itself (McNulty et al., 2006). In the absence of RhsA, KpsD, and KpsE are no longer targeted to the poles of the cell, suggesting that RhsA may be required to stabilize the proposed biosynthetic-export machinery (McNulty et al., 2006). It is less likely to be involved with transport per se, as rhsA mutants are still able to present a K5 capsule, whereas kpsD or kpsE mutants result in periplasmic accumulation of polymer (Bronner et al., 1993). The finding that RhsA is involved in K5 (Group 2) capsule expression is curious. RhsA has been suggested to be a sugar binding protein and possibly be located in the periplasm (Wang et al., 1998). However the low levels of RhsA expression have made detection of the cellular location of RhsA difficult. As such the role of RhsA in Group 2 capsule expression awaits further clarification.
A. Group 2 capsular polysaccharide synthesis and export are linked Biosynthesis and export are likely to be linked, and this linkage is believed to be conserved between capsule groups. Coupling of synthesis and export would avoid the problem of assembling a >100 kDa polymer
Capsular Polysaccharides in Escherichia coli
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and exporting it in separate processes at separate sites, and would increase the efficiency of the process by increasing the effective concentration of the required proteins at any one site in the cell (Rigg et al., 1998; Whitfield and Roberts, 1999). The theory is supported by the fact that a trans-envelope complex appears to be formed from the synthetic and export proteins in both Group 1 and Group 2. Mutations in any gene in region 1 or 3 of Group 2 capsule gene clusters adversely affects capsule biosynthesis, indicating that the processes of synthesis and export are linked (Bronner et al., 1993; Roberts, 1996). Mutation of kpsC, M, S, or T prevents KfiA and KfiC from associating with the inner membrane. Indeed, KfiC is known to be unstable if it fails to localize to the inner membrane (Griffiths et al., 1998; Rigg et al., 1998). More recently, western blot analysis revealed that interactions between the three proteins KfiA, C and D were essential for their stable localization to the bacterial inner membrane (Hodson et al., 2000). KpsD and KpsE localize to the poles of the cell, as shown by immunofluorescence microscopy, suggesting that this is where the biosynthetic complex is formed. It has been shown that polysaccharide export occurs at these sites at the pole of the cell after which the polysaccharide spreads around the surface of the bacterium to form a capsule (McNulty et al., 2006). The mechanism by which this diffusion occurs is unknown, it may be an active process or reflect the lateral diffusion of lipid linked polysaccharide in the outer-leaflet (McNulty et al., 2006). Although KpsD is intrinsically polar, this is not true for KpsE that is held at the pole probably through interactions with KpsD and the capsule biosynthetic complex on the inner-membrane. The biosynthetic complex may itself be targeted to the pole of the cell via the action of KpsS which intrinsically localizes to the poles of the cell, although the mechanism by which this occurs is unknown. In vivo chemical cross-linking of KpsS has provided direct evidence of a trans-envelope complex, stretching from the cytoplasmic face of the inner membrane to the exterior of the cell. The complex includes at least KfiA, KpsM, KpsT, KpsS, KpsE and KpsD (McNulty et al., 2006). Further evidence comes from Group 1 strains. In E. coli K30, Wza and Wzc interact, forming a continuum between the cytoplasm and exterior surface of the cell (Collins et al., 2007), and wza mutants, in addition to failing to express capsule, do not accumulate polymer internally (Nesper et al., 2003). In wzc mutants, the activity of WbaP is markedly reduced (Collins et al., 2007; Nesper et al., 2003), and Wzc has been shown to extend into the cytoplasm, although not in a manner which would form a pore. The exposed ‘‘legs’’ of Wzc may form attachment sites for the rest of the synthetic-export complex (Collins et al., 2007). Transport of capsular polysaccharide to the cell surface is believed to occur at Bayer patches— areas where the inner and outer membranes come into close apposition (Bayer, 1991; Bayer and Thurow, 1977) although the nature of such sites is
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controversial because they can only be visualized with certain methods of preparation (Bayer, 1991). It is possible, but not proven, that the sites at which the capsule export machinery is located coincides with a Bayer junction (McNulty et al., 2006), and recent studies have suggested that the periplasm is compressed at the site of Wza-Wzc interaction (Collins et al., 2007).
IX. REGULATION OF CAPSULE EXPRESSION IN E. coli Given the substantial energy investment that the biosynthesis and export of a capsular polysaccharide represents to bacteria, and that expression of a capsule is not appropriate for bacteria in all circumstances, it is to be expected that capsule expression is tightly regulated. For example, although polysaccharide capsules protect bacteria from the effects of serum-mediated killing, the capsule often prevents intimate adhesion of bacteria to host tissues, and further dissemination into the host. The following sections review the current understanding of capsule regulation in E. coli.
A. Regulation of the E. coli K30 capsule and expression of colanic acid (Slime) in E. coli K-12 strains The principal role of colanic acid appears to be in protection from the external environment, being necessary both for prevention of desiccation and biofilm formation, and its expression is induced in response to osmotic shock (Ophir and Gutnick, 1994; Sledjeski and Gottesman, 1996). Colanic acid can be co-expressed with E. coli polysaccharide capsules of Groups 2, 3, and 4, but not with Group 1. However, the regulation of both colanic acid and Group 1 K antigens is similar, involving the Rcs phosphorelay system, a highly conserved regulatory system amongst the g-proteobacteria. The Rcs phosphorelay system was originally considered a twocomponent regulatory system involving RcsC, RcsB and an accessory protein, RcsA (Gottesman and Stout, 1991). Two-component regulatory systems allow bacteria to couple a stimulus, detected by a sensor protein, to a specific response in the form of altered gene expression. This occurs via a response regulator protein, typically a transcriptional regulator, whose activity the sensor protein controls through phosphorylation of conserved aspartate residues (Stock et al., 2000). However, the model has recently been expanded (Majdalani and Gottesman, 2005), and the system now includes: RcsF, an outer membrane lipoprotein and sensor which is able, by an unknown mechanism, to transduce a signal to RcsC; RcsC is an inner membrane-bound sensor histidine kinase; RcsD,
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a membrane-bound phosphotransfer protein; and RcsB, a transcriptional response regulator. The accessory protein RcsA is also involved in colanic acid gene expression, and provides a layer of regulation independent of the phosphorelay system (Majdalani and Gottesman, 2005). Briefly, a phosphorelay system usually involves the transfer of phosphate from a histidine residue within the sensor, which is typically autophosphorylating, to a conserved aspartate residue within its target. Atypically, RcsC contains a response regulator domain in addition to a histidine kinase domain, but it lacks a histidine phosphotransfer domain. This function is provided by RcsD (Takeda et al., 2001). Upon activation, phosphate is transferred from the kinase domain to the response regulator domain within RcsC. The phosphate moiety is then transferred to a histidine residue within RcsD, and from there to the response regulator RcsB, resulting in its activation. Activated RcsB is able to bind to promoter regions as a homodimer, binding near the –35 region, probably through interaction with RNA polymerase (Majdalani and Gottesman, 2005). However, RcsB is also capable of forming heterodimers with RcsA, which is a target for the ATP-dependent protease Lon (Majdalani and Gottesman, 2005). As a result, RcsA is typically present at very low levels in the cell. RcsAB heterodimer formation shields RcsA from the action of Lon, and permits subsequent direct activation of RcsA-dependent target promoters, including the colanic acid biosynthetic operon. Strains inactivated for lon become independent on RcsC for colanic acid overexpression and present a mucoid phenotype, as the half-life of RcsA is dramatically increased (Gottesman and Stout, 1991). This also suggests that an alternative mechanism for activating RcsB must exist. The binding site is altered to a distantly upstream region containing what has been termed the RcsAB box with a core consensus sequence of TaAGaatatTCctA (Wehland and Bernhard, 2000). Group 1 capsular polysaccharide expression is also upregulated by the Rcs phosphorelay system, resulting in a mucoid phenotype. However, it is not involved in wild type levels of capsule expression as grown under laboratory conditions (Jayaratne et al., 1993). Unlike the colanic acid biosynthetic operon of E. coli K-12, Group 1 capsular polysaccharides are not temperatureregulated and possess no RcsAB box immediately upstream of the capsule gene cluster. Basal transcription of these genes is unaffected by the Rcs phosphorelay system (Rahn and Whitfield, 2003). In these strains, there is an RcsAB box upstream of galF, whose gene product is involved in the synthesis of UDP-glucose, a sugar precursor for capsule synthesis. Multicopy RcsB was found to induce the transcription of galF, concomitant with an increase in K30 expression and a mucoid phenotype (Rahn and Whitfield, 2003). Thus, Group 1 capsule expression is in part regulated by the availability of activated sugar precursors, which in turn may be increased through activation of the Rcs phosphorelay system
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(Rahn and Whitfield, 2003). In addition, both E. coli Group 1 capsule gene clusters and the colanic acid gene cluster are dependent upon a sequence downstream of their promoters known as JUMPStart (Just Upstream of Many Polysaccharide gene Starts) (Hobbs and Reeves, 1994). This is a conserved 39 bp sequence present in the 50 untranslated region (UTR) of many polysaccharide genes, and contains a further conserved GGCGGTAG motif known as ops (operon polarity suppressor) which must be present on the transcribed mRNA of a gene in order to function (Nieto et al., 1996). During transcription, RNA polymerase pauses at the ops sequence whilst the anti-termination factor RfaH interacts with the exposed, noncoding DNA strand in the melted transcription bubble. Transcription elongation is then accelerated, and the RNA polymeraseRfaH complex is subsequently less sensitive to transcription termination signals (Artsimovitch and Landick, 2002; Bailey et al., 2000). Consequently, RfaH is often essential for the transcription of large polysaccharide gene clusters (Bailey et al., 1997). This is true for the K30 gene cluster, which contains a stem-loop transcription-terminating structure between the wzc and wbaP genes. Transcription of the genes downstream of wzc, and eventual expression of the K30 polysaccharide requires RfaH (Rahn and Whitfield, 2003).
B. Regulation of expression of Group 2 (K5) capsule gene clusters Transcription of the K5 polysaccharide gene cluster is driven by two convergent temperature-regulated promoters located upstream of regions 1 and 3 (Fig. 1.1) (Simpson et al., 1996; Stevens et al., 1997). This temperature regulation appears to be controlled at the level of transcription, as no detectable transcription originates from either promoter at 20 C (Cieslewicz and Vimr, 1996; Rowe et al., 2000). Transcriptional regulation of this gene cluster involves the regulatory proteins H-NS, BipA, and IHF, which are discussed in detail below. Transcription of the region 2 genes is driven by PR3 (Fig. 1.1) and because the region 2 promoters are too weak to enable the bacterium to express a capsule (Petit et al., 1995), expression of the K5 capsular polysaccharide is absolutely dependent upon RfaH, which acts on an ops sequence present in the 50 UTR of kpsM (Stevens et al., 1994, 1997). Unlike PR3, there is no dependency upon RfaH for transcription elongation at PR1, and no JUMPStart sequence is present upstream of kpsF (Simpson et al., 1996; Stevens et al., 1997). The IHF protein is required for maximum transcription from PR1 at 37 C and binds to a single site located 130 bp downstream of the transcription start point at PR1 (Fig. 1.1) (Rowe et al., 2000; Tippner et al., 1994; Tupper et al., 1994). Two additional regulators,
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H-NS and BipA play an unusual dual role in the temperature regulation of transcription at this promoter: both are required for maximum transcription at 37 C, yet both also contribute to repression of transcription at 20 C, and the transcriptional effects are mirrored in the levels of K5 capsule produced by the respective mutants (Rowe et al., 2000). The effect of the bipA mutant is unlikely to be the result of modulation of H-NS expression as quantitative western blots showed the level of H-NS to be unchanged by mutation of bipA (Dame et al., 2001; Grant et al., 2003). H-NS and BipA play similar roles at PR3, but there is no evidence of a role for IHF at this promoter (Rowe et al., 2000; Stevens et al., 1997). Unlike many of the other capsule types discussed here, the Rcs phosphorelay system is not involved in expression of the K5 capsule gene cluster (Keenleyside et al., 1993; Stevens et al., 1994). It has been suggested that downregulation of region 1 transcription and capsule expression occurs when UPEC type 1 fimbriae bind to mannose receptors such as those that exist on bladder epithelial cells (Schwan et al., 2005). Preliminary data from strains expressing a fusion of PR1 to a promoterless lacZ gene also indicate that capsule gene transcription is down-regulated during biofilm formation on cellulose-containing surfaces, and that in planktonic phase cultures, sub populations of cells expressing very low or no capsule may exist, and that these are the cells which interact with surfaces and initiate biofilm formation (Ebah and Roberts, 2001). Recently a more detailed understanding of the control of transcription from PR1 has been elucidated which demonstrates that transcription involves a novel interaction between H-NS and the transcriptional activator SlyA (Corbett et al., 2007). These studies have shown that at 37 C maximal expression from PR1 requires the binding of both H-NS and SlyA at the promoter (Corbett et al., 2007). This requirement for H-NS for SlyA mediated activation explains the observation that at 37 C, hns mutants have reduced capsule expression. Whereas reduced SlyA expression at 20 C results in an H-NS dominated nucleoprotein complex repressing transcription from PR1. This model for regulation of transcription in which expression depends on the relative cellular levels of H-NS and SlyA has recently been suggested for regulation of the hlyE gene in E. coli (Lithgow et al., 2007). Recent unpublished data would also suggest that a similar situation exists for the regulation of PR3 (Que and Roberts, unpublished results). The role played by BipA in the regulation of Group 2 capsule gene clusters still awaits elucidation but is likely to be via an as yet unidentified transcriptional activator. The current understanding of the regulation of Group 2 capsule gene clusters is shown in Fig. 1.3.
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−ve at 20⬚C X
H-NS
H-NS
+ve
+ve at 37⬚C
BipA
−ve at 20⬚C +ve at 37⬚C
X SlyA
RfaH
IHF RNaseE/III?
PR3
PR1
kps
F
E
D U
C
T
S kfi
SlyA
D
C
B
M
A
FIGURE 1.3 Regulation of Group 2 capsule gene expression. At 37 C SlyA and H-NS activate transcription from both PR1 and PR3, with SlyA activity being dependent on the binding of H-NS. At 20 C H-NS acts to repress transcription. BipA is a translational regulator, loss of which results in a drop in transcription from PR1 and PR3. As such BipA is postulated to regulate the translation of an as yet unknown transcriptional activator termed X.
X. CONCLUSIONS In the last five years there has been dramatic progress made in our understanding of the expression of capsular polysaccharides by E. coli. The application of structural biology to studying Group 1 polysaccharide export has proved fundamental information on the mechanism by which such polysaccharides are exported out of the cell. It is predicted that similar approaches currently being used to study polysaccharide export of Group 2 polysaccharides will prove equally rewarding. It is also apparent that we are beginning to dissect the complex regulatory pathways that control capsule expression in E. coli, this being particularly true for the regulation of Group 2 capsules. The challenge is to translate these in vitro data into understanding the regulation of polysaccharide expression in the host under conditions of both health and disease. By understanding how capsule expression is regulated in vivo we will be able to better understand the role trhat capsules play during survival and growth in the host. The engineering of polysaccharides in E. coli has meet with some success (Priem et al., 2002; Samain et al., 1999; Yavuz et al., 2008). It is our view that polysaccharide engineering represents an area of great unfulfilled potential, especially when one considers that many polysaccharides of biomedical importance, such as heparin, are still extracted from animal sources. As such there is a clear need for an alternative safe
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biotechnological route to synthesize these molecules. E. coli in many ways represents the ideal host, with it long history as a laboratory organism and clearly E. coli capsular polysaccharides are one source of enzymes for generating diverse polysaccharides in E. coli. However it will be the efficient expression in E. coli of heterologous polysaccharide biosynthesis genes that will offer the route to greatest diversity. The long-term aspiration has to be to exploit E. coli capsular transport functions to effectively export heterologous novel polysaccharide in E. coli thereby facilitating their rapid purification.
REFERENCES Andreishcheva, E. N., and Vann, W. F. (2006). Gene products required for de novo synthesis of polysialic acid in Escherichia coli K1. J. Bacteriol. 188, 1786–1797. Arrecubieta, C., Hammarton, T. C., Barrett, B., Chareonsudjai, S., Hodson, N., Rainey, D., and Roberts, I. S. (2001). The transport of group 2 capsular polysaccharides across the periplasmic space in Escherichia coli. Roles for the KpsE and KpsD proteins. J. Biol. Chem. 276, 4245–4250. Artsimovitch, I., and Landick, R. (2002). The transcriptional regulator RfaH stimulates RNA chain synthesis after recruitment to elongation complexes by the exposed nontemplate DNA strand. Cell 109, 193–203. Bailey, M. J., Hughes, C., and Koronakis, V. (1997). RfaH and the ops element, components of a novel system controlling bacterial transcription elongation. Mol. Microbiol. 26, 845–851. Bailey, M. J., Hughes, C., and Koronakis, V. (2000). In vitro recruitment of the RfaH regulatory protein into a specialised transcription complex, directed by the nucleic acid ops element. Mol. Gen. Genet. 262, 1052–1059. Bayer, M. E. (1991). Zones of membrane adhesion in the cryofixed envelope of Escherichia coli. J. Struct. Biol. 107, 268–280. Bayer, M. E., and Thurow, H. (1977). Polysaccharide capsule of Escherichia coli: microscope study of its size, structure, and sites of synthesis. J. Bacteriol. 130, 911–936. Beis, K., Collins, R. F., Ford, R. C., Kamis, A. B., Whitfield, C., and Naismith, J. H. (2004). Three-dimensional structure of Wza, the protein required for translocation of group 1 capsular polysaccharide across the outer membrane of Escherichia coli. J. Biol. Chem. 279, 28227–28232. Blattner, F. R., Plunkett, G., Bloch, C. A., Perna, N. T., Burland, V., Riley, M., ColladoVides, J., Glasner, J. D., Rode, C. K., Mayhew, G. F., Gregor, J., Davis, N. W., et al. (1997). The complete genome sequence of Escherichia coli K-12. Science 277, 1453–1474. Bliss, J. M., and Silver, R. P. (1996). Coating the surface: A model for expression of capsular polysialic acid in Escherichia coli K1. Mol. Microbiol. 21, 221–231. Boulnois, G. J., and Jann, K. (1989). Bacterial polysaccharide capsule synthesis, export and evolution of structural diversity. Mol. Microbiol. 3, 1819–1823. Bronner, D., Sieberth, V., Pazzani, C., Roberts, I. S., Boulnois, G. J., Jann, B., and Jann, K. (1993). Expression of the capsular K5 polysaccharide of Escherichia coli: Biochemical and electron microscopic analyses of mutants with defects in region 1 of the K5 gene cluster. J. Bacteriol. 175, 5984–5992. Burns, S. M., and Hull, S. I. (1998). Comparison of loss of serum resistance by defined lipopolysaccharide mutants and an acapsular mutant of uropathogenic Escherichia coli O75:K5. Infect. Immun. 66, 4244–4253.
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Burns, S. M., and Hull, S. I. (1999). Loss of resistance to ingestion and phagocytic killing by Oand K-mutants of a uropathogenic Escherichia coli O75:K5 Strain. Infect. Immun. 67, 3757–3762. Ciampi, M. S. (2006). Rho-dependent terminators and transcription termination. Microbiology 152, 2515–2528. Cieslewicz, M., and Vimr, E. (1996). Thermoregulation of kpsF, the first region 1 gene in the kps locus for polysialic acid biosynthesis in Escherichia coli K1. J. Bacteriol. 178, 3212–3220. Cieslewicz, M., and Vimr, E. (1997). Reduced polysialic acid capsule expression in Escherichia coli K1 mutants with chromosomal defects in kpsF. Mol. Microbiol. 26, 237–249. Clarke, B. R., Pearce, R., and Roberts, I. S. (1999). Genetic organization of the Escherichia coli K10 capsule gene cluster: Identification and characterization of two conserved regions in group III capsule gene clusters encoding polysaccharide transport functions. J. Bacteriol. 181, 2279–2285. Collins, R. F., Beis, K., Dong, C., Botting, C. H., McDonnell, C., Ford, R. C., Clarke, B. R., Whitfield, C., and Naismith, J. H. (2007). The 3D structure of a periplasm-spanning platform required for assembly of Group 1 capsular polysaccharides in Escherichia coli. Proc. Natl. Acad. Sci. USA 104, 2390–2395. Corbett, D., Bennett, H., Askar, H., Green, J., and Roberts, I. S. (2007). SlyA and H-NS regulate transcription of the Escherichia coli K5 capsule gene cluster and expression of slyA in Escherichia coli is temperature dependent, positively autoregulated and independent of H-NS. J. Biol. Chem. 282, 33326–33335. Cywes, C., and Wessels, M. R. (2001). Group A Streptococcus tissue invasion by CD44mediated cell signalling. Nature 414, 648–652. Dame, R. T., Wyman, C., and Goosen, N. (2001). Structural basis for preferential binding of H-NS to curved DNA. Biochimie 83, 231–234. Dodgson, C., Amor, P., and Whitfield, C. (1996). Distribution of the rol gene encoding the regulator of lipopolysaccharide O-chain length in Escherichia coli and its influence on the expression of group I capsular K antigens. J.Bacteriol. 178, 1895–1902. Dong, C., Beis, K., Nesper, J., Brunkan-Lamontagne, A. L., Clarke, B. R., Whitfield, C., and Naismith, J. H. (2006). Wza the translocon for E. coli capsular polysaccharides defines a new class of membrane protein. Nature 444, 226–229. Drummelsmith, J., and Whitfield, C. (1999). Gene products required for surface expression of the capsular form of the Group 1 K antigen in Escherichia coli (O9a:K30). Mol. Microbiol. 31, 1321–1332. Drummelsmith, J., and Whitfield, C. (2000). Translocation of Group 1 capsular polysaccharide to the surface of Escherichia coli requires a multimeric complex in the outer membrane. EMBO J. 19, 57–66. Ebah, L., and Roberts, I. S. (2001). Regulation of the Escherichia coli K5 capsule gene cluster during biofilm development. In ‘‘Biofilm Community Interactions: Chance or Necessity’’ (P. Gilbert, D. Allison, M. Brading, J. Verran and J. Walker, Eds.), pp. 211–219. BioLine, Gregynog Hall, Powys, Wales. Finke, A., Bronner, D., Nikolaev, A. V., Jann, B., and Jann, K. (1991). Biosynthesis of the Escherichia coli K5 polysaccharide, a representative of group II capsular polysaccharides: Polymerization in vitro and characterization of the product. J. Bacteriol. 173, 4088–4094. Frosch, M., Edwards, U., Bousset, K., Krausse, B., and Weisgerber, C. (1991). Evidence for a common molecular origin of the capsule gene loci in gram-negative bacteria expressing group II capsular polysaccharides. Mol. Microbiol. 5, 1251–1263. Gottesman, S., and Stout, V. (1991). Regulation of capsular polysaccharide synthesis in Escherichia coli K12. Mol. Microbiol. 5, 1599–1606. Grant, A. J., Farris, M., Alefounder, P., Williams, P. H., Woodward, M. J., and O’Connor, C. D. (2003). Co-ordination of pathogenicity island expression by the BipA GTPase in enteropathogenic Escherichia coli (EPEC). Mol. Microbiol. 48, 507–521.
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Griffiths, G., Cook, N. J., Gottfridson, E., Lind, T., Lidholt, K., and Roberts, I. S. (1998). Characterization of the glycosyltransferase enzyme from the Escherichia coli K5 capsule gene cluster and identification and characterization of the glucuronyl active site. J. Biol. Chem. 273, 11752–11757. Hobbs, M., and Reeves, P. R. (1994). The JUMPstart sequence: A 39bp element common to several polysaccharide gene clusters. Mol. Microbiol. 12, 855–856. Hodson, N., Griffiths, G., Cook, N., Pourhossein, M., Gottfridson, E., Lind, T., Lidholt, K., and Roberts, I. S. (2000). Identification that KfiA, a protein essential for the biosynthesis of the Escherichia coli K5 capsular polysaccharide, is an alpha -UDP-GlcNAc glycosyltransferase. The formation of a membrane-associated K5 biosynthetic complex requires KfiA, KfiB, and KfiC. J. Biol. Chem. 275, 27311–27315. Jann, K., and Jann, B. (1997). Capsules of Escherichia coli. In ‘‘Escherichia coli Mechanisms of Virulence’’ (M. Sussman, Ed.), pp. 113–144. The Press Syndicate of the University of Cambridge, Cambridge. Jayaratne, P., Keenleyside, W. J., MacLachlan, P. R., Dodgson, C., and Whitfield, C. (1993). Characterization of rcsB and rcsC from Escherichia coli O9:K30:H12 and examination of the role of the rcs regulatory system in expression of group I capsular polysaccharides. J. Bacteriol. 175, 5384–5394. Kaijser, B., and Jodal, U. (1984). Escherichia coli K5 antigen in relation to various infections and in healthy individuals. J. Clin. Microbiol. 19, 264–266. Keenleyside, W. J., Jayaratne, P., MacLachlan, P. R., and Whitfield, C. (1992). The rcsA gene of Escherichia coli O9:K30:H12 is involved in the expression of the serotype-specific Group I K (capsular) antigen. J. Bacteriol. 174, 8–16. Keenleyside, W. J., Bronner, D., Jann, K., Jann, B., and Whitfield, C. (1993). Coexpression of colanic acid and serotype-specific capsular polysaccharides in Escherichia coli strains with Group II K antigens. J. Bacteriol. 175, 6725–6730. Kim, K. J., Elliott, S. J., Di Cello, F., Stins, M. F., and Kim, K. S. (2003). The K1 capsule modulates trafficking of E. coli-containing vacuoles and enhances intracellular bacterial survival in human brain microvascular endothelial cells. Cell Microbiol. 5, 245–252. Lithgow, J. K., Haider, F., Roberts, I. S., and Green, J. (2007). Alternate SlyA and H-NS nucleoprotein complexes control hlyE expression in Escherichia coli K-12. Mol. Microbiol. 66, 685–698. Majdalani, N., and Gottesman, S. (2005). The Rcs phosphorelay: A complex signal transduction system. Annu. Rev. Microbiol. 59, 379–405. McNulty, C., Thompson, J., Barrett, B., Lord, L., Andersen, C., and Roberts, I. S. (2006). The cell surface expression of group 2 capsular polysaccharides in Escherichia coli: The role of KpsD, RhsA and a multiprotein complex at the pole of the cell. Mol. Microbiol. 59, 907–922. Meredith, T. C., and Woodard, R. W. (2006). Characterization of Escherichia coli D-arabinose 5-phosphate isomerase encoded by kpsF: Implications for group 2 capsule biosynthesis. Biochem. J. 395, 427–432. Munoz, R., Garcia, E., and Lopez, R. (1998). Evidence for horizontal transfer from Streptococcus to Escherichia coli of the kfiD gene encoding the K5-specific UDP-glucose dehydrogenase. J. Mol. Evol. 46, 432–436. Nesper, J., Hill, C. M., Paiment, A., Harauz, G., Beis, K., Naismith, J. H., and Whitfield, C. (2003). Translocation of group 1 capsular polysaccharide in Escherichia coli serotype K30. Structural and functional analysis of the outer membrane lipoprotein Wza. J. Biol. Chem. 278, 49763–49772. Nieto, J. M., Bailey, M. J., Hughes, C., and Koronakis, V. (1996). Suppression of transcription polarity in the Escherichia coli haemolysin operon by a short upstream element shared by polysaccharide and DNA transfer determinants. Mol. Microbiol. 19, 705–713. Nsahlai, C. J., and Silver, R. P. (2003). Purification and characterization of KpsT, the ATPbinding component of the ABC-capsule exporter of Escherichia coli K1. FEMS Microbiol. Lett. 224, 113–118.
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Ophir, T., and Gutnick, D. (1994). A role for exopolysaccharides in the protection of microorganisms from desiccation. Appl. Environ. Microbiol. 60, 740–745. Paiment, A., Hocking, J., and Whitfield, C. (2002). Impact of phosphorylation of specific residues in the tyrosine autokinase, Wzc, on its activity in assembly of group 1 capsules in Escherichia coli. J. Bacteriol. 184, 6437–6447. Paulsen, I. T., Beness, A. M., and Saier, M. H. (1997). Computer-based analyses of the protein constituents of transport systems catalysing export of complex carbohydrates in bacteria. Microbiology 143, 2685–2699. Pavelka, M. S., Hayes, S. F., and Silver, R. P. (1994). Characterization of KpsT, the ATPbinding component of the ABC-transporter involved with the export of capsular polysialic acid in Escherichia coli K1. J. Biol. Chem. 269, 20149–20158. Pearce, R., and Roberts, I. S. (1995). Cloning and analysis of gene clusters for production of the Escherichia coli K10 and K54 antigens: Identification of a new group of serA-linked capsule gene clusters. J. Bacteriol. 177, 3992–3997. Peleg, A., Shifrin, Y., Ilan, O., Nadler-Yona, C., Nov, S., Koby, S., Baruch, K., Altuvia, S., Elgrably-Weiss, M., Abe, C. M., Knutton, S., Saper, M. A., et al. (2005). Identification of an Escherichia coli operon required for formation of the O-antigen capsule. J. Bacteriol. 187, 5259–5266. Petit, C., Rigg, G. P., Pazzani, C., Smith, A., Sieberth, V., Stevens, M., Boulnois, G. J., Jann, K., and Roberts, I. S. (1995). Region 2 of the Escherichia coli K5 capsule gene cluster encoding proteins for the biosynthesis of the K5 polysaccharide. Mol. Microbiol. 17, 611–620. Pigeon, R. P., and Silver, R. P. (1997). Analysis of the G93E mutant allele of KpsM, the membrane component of an ABC transporter involved in polysialic acid translocation in Escherichia coli K1. FEMS Microbiol. Lett. 156, 217–222. Priem, B., Gilbert, M., Wakarchuk, W. W., Heyraud, A., and Samain, E. (2002). A new fermentation process allows large scale production of human milk oligosaccharides by metabolically engineered bacteria. Glycobiology 12, 235–240. Rahn, A., and Whitfield, C. (2003). Transcriptional organization and regulation of the Escherichia coli K30 group 1 capsule biosynthesis (cps) gene cluster. Mol. Microbiol. 47, 1045–1060. Rahn, A., Drummelsmith, J., and Whitfield, C. (1999). Conserved organization in the cps gene clusters for expression of Escherichia coli group 1 K antigens: Relationship to the colanic acid biosynthesis locus and the cps genes from Klebsiella pneumoniae. J. Bacteriol. 181, 2307–2313. Rahn, A., Beis, K., Naismith, J. H., and Whitfield, C. (2003). A novel outer membrane protein, Wzi, is involved in surface assembly of the Escherichia coli K30 group 1 capsule. J. Bacteriol. 185, 5882–5890. Rigg, G. P., Barrett, B., and Roberts, I. S. (1998). The localization of KpsC, S and T, and KfiA, C and D proteins involved in the biosynthesis of the Escherichia coli K5 capsular polysaccharide: Evidence for a membrane-bound complex. Microbiology 144, 2905–2914. Roberts, I. S. (1996). The biochemistry and genetics of capsular polysaccharide production in bacteria. Annu. Rev. Microbiol. 50, 285–315. Roberts, I. S. (2000). Transcriptional organisation and regulation of E. coli Group 2 capsule expression. Adv. Exp. Med. Biol. 485, 95–101. Roman, E., Roberts, I. S., Lidholt, K., and Kusche-Gullberg, M. (2003). Overexpression of UDP-glucose dehydrogenase in Escherichia coli results in decreased biosynthesis of K5 polysaccharide. Biochem. J. 374, 767–772. Rosenow, C., Esumeh, F., Roberts, I. S., and Jann, K. (1995). Characterization and localization of the KpsE protein of Escherichia coli K5, which is involved in polysaccharide export. J. Bacteriol. 177, 1137–1143. Rosenow, C., Roberts, I. S., and Jann, K. (1995). Isolation from recombinant Escherichia coli and characterization of CMP-Kdo synthetase, involved in the expression of the capsular K5 polysaccharide (K-CKS). FEMS Microbiol. Lett. 125, 159–164.
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Rowe, S., Hodson, N., Griffiths, G., and Roberts, I. S. (2000). Regulation of the Escherichia coli K5 capsule gene cluster: Evidence for the roles of H-NS, BipA, and integration host factor in regulation of Group 2 capsule gene clusters in pathogenic E. coli. J. Bacteriol. 182, 2741–2745. Russo, T. A., Wenderoth, S., Carlino, U. B., Merrick, J. M., and Lesse, A. J. (1998). Identification, genomic organization, and analysis of the Group III capsular polysaccharide genes kpsD, kpsM, kpsT, and kpsE from an extraintestinal isolate of Escherichia coli (CP9, O4/ K54/H5). J. Bacteriol. 180, 338–349. Samain, E., Chazalet, V., and Geremia, R. A. (1999). Production of O-acetylated and sulphated chito-oligosaccharides by recombinant Escherichia coli strains harbouring different combinations of nod genes. J. Biotechnol. 72, 33–47. Saxena, I. M., Brown, R. M., Fevre, M., Geremia, R. J., and Henrissat, B. (1995). Multidomain architecture of beta-glycosyl transferases: Implications for mechanism of action. J. Bacteriol. 177, 1419–1424. Schlor, S., Schmidt, A., Maier, E., Benz, R., Goebel, W., and Gentschev, I. (1997). In vivo and in vitro studies on interactions between the components of the hemolysin (HlyA) secretion machinery of Escherichia coli. Mol. Gen. Genet. 256, 306–319. Schwan, W. R., Beck, M. T., Hultgren, S. J., Pinkner, J., Woolever, N. L., and Larson, T. (2005). Down-regulation of the kps region 1 capsular assembly operon following attachment of Escherichia coli type 1 fimbriae to d-mannose receptors. Infect. Immun. 73, 1226–1231. Sieberth, V., Rigg, G. P., Roberts, I. S., and Jann, K. (1995). Expression and characterization of UDPGlc dehydrogenase (KfiD), which is encoded in the type-specific region 2 of the Escherichia coli K5 capsule genes. J. Bacteriol. 177, 4562–4565. Silver, R. P., Prior, K., Nsahlai, C., and Wright, L. F. (2001). ABC transporters and the export of capsular polysaccharides from gram-negative bacteria. Res. Microbiol. 152, 357–364. Simpson, D. A., Hammarton, T. C., and Roberts, I. S. (1996). Transcriptional organization and regulation of expression of region 1 of the Escherichia coli K5 capsule gene cluster. J. Bacteriol. 178, 6466–6474. Sledjeski, D. D., and Gottesman, S. (1996). Osmotic shock induction of capsule synthesis in Escherichia coli K-12. J. Bacteriol. 178, 1204–1206. Stevens, M. P., Hanfling, P., Jann, B., Jann, K., and Roberts, I. S. (1994). Regulation of Escherichia coli K5 capsular polysaccharide expression: Evidence for involvement of RfaH in the expression of Group II capsules. FEMS Microbiol. Lett. 124, 93–98. Stevens, M. P., Clarke, B. R., and Roberts, I. S. (1997). Regulation of the Escherichia coli K5 capsule gene cluster by transcription antitermination. Mol. Microbiol. 24, 1001–1012. Stock, A. M., Robinson, V. L., and Goudreau, P. N. (2000). Two-component signal transduction. Annu. Rev. Biochem. 69, 183–215. Takeda, S., Fujisawa, Y., Matsubara, M., Aiba, H., and Mizuno, T. (2001). A novel feature of the multistep phosphorelay in Escherichia coli: A revised model of the RcsC -->YojN --> RcsB signalling pathway implicated in capsular synthesis and swarming behaviour. Mol. Microbiol. 40, 440–450. Thanabalu, T., Koronakis, E., Hughes, C., and Koronakis, V. (1998). Substrate-induced assembly of a contiguous channel for protein export from E.coli: Reversible bridging of an inner-membrane translocase to an outer membrane exit pore. EMBO J. 17, 6487–6496. Tippner, D., Afflerbach, H., Bradaczek, C., and Wagner, R. (1994). Evidence for a regulatory function of the histone-like Escherichia coli protein H-NS in ribosomal RNA synthesis. Mol. Microbiol. 11, 589–604. Tupper, A. E., Owen-Hughes, T. A., Ussery, D. W., Santos, D. S., Ferguson, D. J., Sidebotham, J. M., Hinton, J. C., and Higgins, C. F. (1994). The chromatin-associated protein H-NS alters DNA topology in vitro. EMBO J. 13, 258–268. Tzeng, Y. L., Datta, A., Strole, C., Kolli, V. S., Birck, M. R., Taylor, W. P., Carlson, R. W., Woodard, R. W., and Stephens, D. S. (2002). KpsF is the arabinose-5-phosphate isomerase
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required for 3-deoxy-D-manno-octulosonic acid biosynthesis and for both lipooligosaccharide assembly and capsular polysaccharide expression in Neisseria meningitidis. J. Biol. Chem. 277, 24103–24113. Wang, Y. D., Zhao, S., and Hill, C. W. (1998). Rhs elements comprise three subfamilies which diverged prior to acquisition by Escherichia coli. J. Bacteriol. 180, 4102–4110. Wehland, M., and Bernhard, F. (2000). The RcsAB box. Characterization of a new operator essential for the regulation of exopolysaccharide biosynthesis in enteric bacteria. J. Biol. Chem. 275, 7013–7020. Whitfield, C. (2006). Biosynthesis and assembly of capsular polysaccharides in Escherichia coli. Annu. Rev. Biochem. 75, 39–68. Whitfield, C., and Roberts, I. S. (1999). Structure, assembly and regulation of expression of capsules in Escherichia coli. Mol. Microbiol. 31, 1307–1319. Wugeditsch, T., Paiment, A., Hocking, J., Drummelsmith, J., Forrester, C., and Whitfield, C. (2001). Phosphorylation of Wzc, a tyrosine autokinase, is essential for assembly of Group 1 capsular polysaccharides in Escherichia coli. J. Biol. Chem. 276, 2361–2371. Yavuz, E., Drouillard, S., Samain, E., Roberts, I. S., and Priem, B. (2008). Glucuronylation in Escherichia coli for the bacterial synthesis of the carbohydrate moiety of nonsulphated HNK-1. Glycobiology 18, 152–157.
CHAPTER
2 Microbial PAH Degradation Evelyn Doyle, Lorraine Muckian, Anne Marie Hickey, and Nicholas Clipson
Contents
I. Introduction II. Polycyclic Aromatic Hydrocarbons (PAHs) A. Toxicity B. Sources of PAHs C. Environmental contamination III. Degradation of PAHs A. Pure culture studies B. Culture-independent analysis C. Marker genes IV. Bioremediation of PAH Contaminated Environments A. Factors affecting bioremediation V. Conclusions References
27 28 28 33 33 34 35 38 45 50 51 53 54
I. INTRODUCTION Since the Industrial Revolution, human activity has created a legacy of environmental contamination widespread through industrialized economies (Baveye et al., 1999). As modern economies move to postindustrial economic activity, and heavy industry retreats, more sites affected with by-products from industrial processes are revealed, especially as environmental protection, legislation, and monitoring become more effective, and also as ‘‘brown’’ land is released for other uses (Philp et al., 2005). Environmental Microbiology Group, School of Biology and Environmental Science, University College Dublin, Ardmore House, Belfield, Dublin 4, Ireland Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00602-3
#
2008 Elsevier Inc. All rights reserved.
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One of the challenges facing postindustrial societies is to develop effective strategies to rehabilitate polluted environments. Many strategies have been advanced to counter these problems, including physical and chemical approaches such as incineration or soil washing. A potentially effective strategy for some polluted sites is the development of biologically based treatments that exploit the degradative ability of microorganisms. The US EPA has estimated that an average of 294,000 contaminated sites require remediation in the next 25 years, at a cost of approximately $209 billion (US EPA, 2004). Between 1982 and 2002, bioremediation was only used at 6% of contaminated sites on the US national priority list. Clearly, industry faces very large costs to remediate sites under the ‘‘polluter pays’’ principle, and there is a need to develop the most costefficient approaches for ‘‘clean-up.’’ Bioremediation technologies are often more cost efficient than physical or chemical approaches to site remediation (Levin and Gealt, 1993; Wood, 1997). Although biologically based processes have clear cost and environmental advantages, there is incomplete understanding of how these work at the microbial level. For large sites, in situ remediation is often desirable where natural microbial communities are exploited and stimulated. In the last 10 years, developments in molecular ecology mean that more sophisticated analysis of degradative communities is possible.
II. POLYCYCLIC AROMATIC HYDROCARBONS (PAHs) PAHs are a diverse group of over 100 organic compounds containing two or more fused benzene and/or pentacyclic ring structures, in linear, angular, or cluster arrangements (Table 2.1). They are thermodynamically stable due to their negative resonance energy and possess high melting and boiling points together with low water solubilities and vapor pressures (WHO, 1998). The chemical properties and environmental fate of PAHs depend on the number of aromatic rings present, and the nature of the linkage between these rings. PAHs are generally divided into low molecular weight PAHs (compounds containing up to three aromatic rings) and high molecular weight PAHs (containing four or more aromatic rings). The hydrophobicity, recalcitrance, and toxicity of these compounds increase as the number of aromatic rings present increases (Cerniglia, 1992). Low molecular weight PAHs tend to be more soluble and volatile, and have less affinity for surfaces than high molecular weight PAHs and thus have lesser tendency to accumulate (WHO, 1998).
A. Toxicity Exposure to PAHs has long been recognized as a significant health risk (Miller and Miller, 1981) and many of these compounds are listed as priority pollutants by both the US EPA and the European Union due to
TABLE 2.1
Chemical and physical properties of the 16 PAHs considered priority pollutants (ATSDR, 2005)
PAH
Chemical formula
Molecular weight
Boiling point ( C)
Melting point ( C)
Solubility (mg l1)
Physical appearance
C10H8
128
218
77
31
White crystals
C12H10
154
279
95
3.8
White or pale yellow crystalline powder
C12H8
152
280
94
16.1
Yellow crystalline powder
C14H10
178
340
218
0.045
Off-white to pale green crystals
C14H10
178
340
99.5
1.1
White crystals
C13H10
166
295
116
1.9
White crystals
Naphthalene
Acenaphthene
Acenaphthylene
Anthracene
Phenanthrene
Fluorene (continued)
TABLE 2.1 (continued)
30 PAH
Chemical formula
Molecular weight
Boiling point ( C)
Melting point ( C)
Solubility (mg l1)
Physical appearance
C16H10
203
375
111
0.26
Light yellow needles
C18H12
228
438
158
0.011
Colorless to yellowbrown flakes
C18H12
228
448
253
0.0015
Crystalline powder
C16H10
202
404
145
0.132
Colorless to light yellow solid
C20H12
252
495
179
0.0038
Yellow crystals
Fluoranthene
Benzo[a]anthracene
Chrysene
Pyrene
Benzo[a]pyrene
C20H12
252
481
168
0.0015
Colorless crystals
C20H12
252
480
216
0.0008
Yellow crystals
C22H14
278
524
266
0.0005
White to yellow crystalline solid
C22H12
276
550
277
0.00026
Large pale yellow– green crystals
C22H12
276
536
162
0.062
Crystalline solid
Benzo[b]fluoranthene
Benzo[k]fluoranthene
Dibenzo[a,h] anthracene
Benzo[g,h,i]perylene
Indeno[1,2,3-cd]pyrene
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their toxic, mutagenic, or carcinogenic properties (ATSDR, 2005). PAH exposure can occur via inhalation, ingestion, or dermal contact, and PAHs have also been reported to cross the placenta causing adverse effects to the embryo and fetus (Collins et al., 1991; Srivastava et al., 1986). Minimal risk levels for human exposure to PAHs have been determined where sufficient toxicological data is available (Table 2.2). Once ingested, PAHs are rapidly absorbed by the gastro-intestinal tract owing to their high lipid solubility. Metabolism of PAHs in mammals results in the production of reactive epoxide and quinone intermediates via a cytochrome P450 monooxygenase mediated reaction (Sutherland et al., 1995). These intermediates may subsequently be oxidized/hydrolyzed prior to forming covalent adducts with DNA, which can result in mutations and ultimately cancer (Bigger et al., 1983). Cases of lung, liver, intestine, pancreas, and skin cancer have all been associated with PAHs (Samanta et al., 2002). The degree of toxicity is generally related to the molecular weight of the PAH, with the higher molecular weight compounds often exhibiting greater toxicity, although the route of exposure and presence of other toxic substances will influence the toxicological effects. Carcinogenicity is particularly associated with high molecular weight PAHs such as benzo[a]pyrene. Mutagenicity studies have indicated that the only PAHs that are clearly not mutagenic are naphthalene, fluorene, and anthracene (Bamford and Singleton, 2005; Cerniglia, 1992; Juhasz and Naidu, 2000).
TABLE 2.2 Minimal risk levels (MRLs) for human exposure to PAHs (ATSDR, 2008)
PAH
Acenaphtene Anthracene Fluoranthene Fluorene Naphthalene
1-methyl naphthalene 2-methyl naphthalene
Exposure route
Duration of exposure
MRL
Oral Oral Oral Oral Inhalation Oral Oral Oral
Intermediate Intermediate Intermediate Intermediate Chronic Acute Intermediate Chronic
0.6 mg/kg/day 10 mg/kg/day 0.4 mg/kg/day 0.4 mg/kg/day 0.0007 ppm 0.6 mg/kg/day 0.6 mg/kg/day 0.07 mg/kg/day
Oral
Chronic
0.04 mg/kg/day
Acute ¼ 1–14 days. Intermediate ¼>14–364 days; Chronic 365 days or longer. MRLs represent the minimal level of human exposure to a compound that is likely to be without appreciable risk of adverse noncancer health effects over a specified duration of exposure. Values are derived only for compounds where reliable and sufficient data exist for a specific duration for a given route of exposure to the substance.
Microbial PAH Degradation
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B. Sources of PAHs PAHs originate from both natural and anthropogenic sources (Blumer, 1976; Mueller et al., 1996). They are natural components of fossil fuels such as petroleum and coal, and may enter the environment as a result of accidental spills and natural leakage of these products. PAHs are also formed during the incomplete combustion of organic matter during volcanic activity, forest and prairie fires, fossil fuel combustion, waste incineration, and to a lesser extent, the cooking of food (Maliszewska-Kordybach, 1999). Other significant sources of PAHs include coal tar and creosote, both by-products of coke production. Coal tar residue is a by-product of coal gasification and up to 300 g kg1 total PAHs have been reported in soils at abandoned coal gasification sites (Sutherland et al., 1995). Creosote, a high temperature distillate of coal tar, has been used for over a century in the wood preservation industry, and consists of a complex mixture of organic chemicals including phenols (5%), N-, S-, and O-heterocyclics (10%), and polycyclic aromatic hydrocarbons (85%) (Rasmussen and Olsen, 2004). Due to the known hazards associated with many of the components of creosote, many countries have introduced restrictions regarding its use. In the US and most European countries only people licensed to use pesticides can apply creosote or handle creosote-treated wood.
C. Environmental contamination Due to their ubiquitous nature, PAHs are found in a wide range of environments including soils, sediments, groundwaters, and the atmosphere. They have been detected in motor engine emissions, tobacco smoke, and in foods such as charcoal-grilled or smoked meats, smoked fish, leafy vegetables, and fats and oils (Maliszewska-Kordybach, 1999; Trapido, 1999). Over 95% of the PAHs (1000 tonne/year) emitted from UK sources into the atmosphere, emanate from unregulated fires, vehicle emissions, and domestic coal consumption (Wright and Welbourn, 2002). In aquatic environments, PAHs tend to adsorb to particulate organic matter and most PAH contamination in these environments is concentrated in sediments, or associated with the presence of suspended solids in surface waters (Basu et al., 1987). For example, Mediterranean sediments have been reported to contain between 1 and 20,500 ng g1 PAHs (Baumard et al., 1998). The concentration of PAHs in surface and groundwaters is typically lower, with Menzie et al. (1992) reporting total PAH concentrations ranging from 0.1 to 829 ng l1 in surface waters in the USA. It is estimated that most of the total environmental PAH load (90%) is found in terrestrial ecosystems, and more specifically, the top 20 cm of the soil horizon ( Jones et al., 1989; Maliszewska-Kordybach, 1996, 1999). Soils surrounding crude-oil refineries, fuel storage depots, manufactured gas
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Evelyn Doyle et al.
plants, and wood preservation facilities are some of the more common sites where industrial scale PAH pollution has been detected (Mahro et al., 1994; Wilson and Jones, 1993). Criteria for acceptable levels of PAHs in soil vary and many countries have yet to publish soil guideline values (SGVs). Where they exist, guidelines are based on an assessment of the risk posed to human health from exposure to contaminated soil and values depend on planned end use (i.e., agricultural, residential, industrial, etc). In some jurisdictions, guidelines refer to the cumulative concentration of several PAHs, whereas others use the concentration of the carcinogenic PAH, benzo[a]pyrene alone (Mueller et al., 1996). Guidelines generally refer to soil intervention and target values. Soil concentrations above the intervention value are considered to pose an unacceptable risk to human health, and target values represent background levels of PAHs in soils. The Dutch Ministry of Housing, Spatial Planning, and Environment (VROM) apply an intervention value of 40 mg total PAHs kg1 dry weight of soil and a target value of 1 mg kg1 (Swartjes, 1999; VROM, 2000); these criteria are often used as a reference point by countries which have yet to develop guidelines.
III. DEGRADATION OF PAHs Numerous abiotic and biotic factors affect PAH degradation in environments such as soil (Fig. 2.1). The number of aromatic rings present and the chemical properties of the PAH have a major effect on its environmental fate, with higher molecular weight compounds persisting for longer Soil-PAH contact time pH
Molecular weight Concentration
Presence of alternative C source Soil properties
PAH properties
Mass transfer
Ring structure
Nutrient content
Water solubility Hydrophobicity Bioavailability
Porosity PAH degradation
Temperature
Organic matter content
Diversity Species abundance Prior exposure Microbial ecology Surfactant production Substrate range Metabolic pathways Substrate affinity
FIGURE 2.1
Abiotic and biotic factors affecting PAH degradation in soil.
Microbial PAH Degradation
35
periods than their lower molecular weight counterparts. For example, the half-life of the 3-ring PAH phenanthrene in soil varied between 16 and 126 days, whilst the 5-ring PAH benzo[a]pyrene had a half life of up to 4 years (Dabestani and Ivanov, 1999; Wickle, 2000). Although abiotic factors such as pH, moisture content, oxygen levels, and nutrient availability influence PAH degradation, it is clear that microbial processes are largely responsible for most degradation (Alexander, 1999; Bossert and Compeau, 1995). If in situ microbial processes are to be effectively exploited to accelerate PAH removal from contaminated environments, greater understanding is required of organisms involved and the processes they mediate.
A. Pure culture studies Culture-based approaches have been used to profile PAH degrading microbial activity in polluted environments. These have included isolation and enrichment of pollutant degrading microorganisms (Heitkamp and Cerniglia, 1988; Mueller et al., 1997), most probable number (MPN), estimates of degraders (Sarkar et al., 2005; Vinas et al., 2005), and estimates of microbial community activity using enzyme assays (Eggen, 1999; Margesin et al., 2000). These approaches have resulted in the isolation of a range of PAH degrading microorganisms, which have been used to elucidate the metabolism of PAHs by specific microbial isolates. Examples of the more commonly isolated organisms are outlined in Table 2.3. Metabolism of PAHs is best understood for low molecular weight compounds, with a considerable amount of information now existing for the pathways, enzymes, and genetics of PAH degradation particularly amongst the pseudomonads (Cerniglia, 1993; Davies and Evans, 1964; Ensley et al., 1982; Gibson and Parales, 2000). Microorganisms have been found to degrade PAHs as carbon and energy sources, as a means of reducing PAH toxicity and as co-metabolic substrates ( Johnsen et al., 2005; Wilson and Jones, 1993). The rate and extent of degradation depend on the number of rings in the specific PAH, with high molecular weight PAHs more resistant to degradation. To date, few bacteria have been isolated that are capable of utilizing PAHs with four or more aromatic rings as sole sources of carbon and energy (Kanaly and Harayama, 2000). Bacterial degradation of PAHs usually proceeds via an initial oxidation of the PAH to a catechol, which is subsequently hydrolyzed to TCA intermediates (Fig. 2.2). Bacteria typically incorporate two molecules of oxygen into one of the benzene rings through the action of intracellular dioxygenases, forming a cis-dihydrodiol that is subsequently converted to a catechol. Ortho- or meta-cleavage of the catechol yields aliphatic products, which may then be channeled into central metabolism. Once the
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TABLE 2.3 Examples of PAH-degrading bacteria, fungi, and algae Organism
Bacteria Pseudomonas spp., Rhodococcus spp., Mycobacterium spp., Sphingomonas spp., Acinetobacter spp., Alcaligenes spp., Flavobacterium spp., Nocardia spp., Xanthomonas spp., Comamonas spp., Agrobacterium spp., Aeromonas spp., Arthrobacter spp., Acidovorax spp., Brevibacterium spp., Corynebacterium spp., Micrococcus spp., Streptomyces spp., Vibrio spp., Bacillus spp., Moraxella spp., Stentrophomonas spp., Aquamicrobium spp., Rhizobium spp.
Selected reference
Mueller et al. (1989, 1990), Davies and Evans (1964), Hickey et al. (2007), Walter et al. (1991), Juhasz et al. (1997), Kelley et al. (1993), Boldrin et al. (1993), Ye et al. (1996), Ryu et al. (1989), Kiyohara et al. (1976a,b), Wikada et al. (2002), Trzesicks-Mlynaz and Ward (1995), Zeinali, 2007; Hamann et al. (1999), Aitken et al. (1998), Kueth and Rehm (1991), Samanta et al. (1999), Dua and Meera (1981), Ghosh and Mishra (1983), Sutherland et al. (1990), West et al. (1984), Stucki and Alexander (1987), Andreoni et al. (2004), Weissenfels et al. (1990)
Fungi Phanerochaete chrysosporium, Pleurotus Cerniglia (1992), Allard and ostreatus, Penicillium spp., Neilson (1997), Harayama Phanerochaete sordida, (1997), Eggen (1999), Johnsen Cunninghamella spp., Cunninghamella et al. (2005) elegans, Aspergillus spp., Rhizopus spp., Bjerkandera sp. Cyanobacteria and Algae Anabaena sp., Aphanocapsa sp., Cerniglia et al. (1985), Narro et al. (1992a, b) Petalonia sp., Chlamydomonas sp., Chorella sp., Coccochloris sp., Dunaliella sp., Nostoc sp., Oscillatoria sp., Porphyridium sp.
initial hydroxylated aromatic ring is degraded, the second ring is attacked in the same manner (Kelley et al., 1991, 1993). Fungi appear to oxidize PAHs as a means of detoxifying these compounds rather than as an initial step in their assimilation (Cerniglia et al., 1985). Nonligninolytic fungi generally oxidize PAHs via cytochrome P450 monoxygenases, resulting in the production of an arene oxide that is
37
Microbial PAH Degradation
O-glucoside
OH atic nzym Non-e ngement a rr a re
H
O-xyloside
Phenol O
R Ba ct er ia ,f C u yt O ng m oc i, 2 on hr al o ga oo m e xy e ge Pna 45 se 0
O-glucuronide O-sulphate
R
H
Arene oxide
H
HO 2 Epox ide h ydrola s
OH e
R
OH H
Trans-dihydrodiol
lignin White rot fu perox idase ngi s, lac case s
R PAH
PAH-quinones Ba
Ring fission
ct
D
er ia O ,a
COOH
lg ae
ge
xy io
2
Orth
na
H
se
NAD+
OH
OH R
OH
n
Fissio
COOH
Cis,cis-muconic acid
Dehydrogenase
OH
H
Cis-dihydrodiol
R
o
Catechol NADH + H+
Meta Fissio
n
CHO COOH R OH
2-hydroxymuconic semialdehyde
FIGURE 2.2 Possible pathways used by microorganisms to degrade PAHs (Cerniglia, 1992).
subsequently hydrolyzed by an epoxide hydrolase to a trans-dihydrodiol (Fig. 2.2). While many of these fungi can transform PAHs to transdihydrodiols and other oxidized products such as phenols, tetralones, quinones, dihydrodiol epoxides, and various conjugates of the hydroxylated intermediates, few have the ability to mineralize PAHs (Mueller et al., 1996). Fungal metabolites produced are often more water-soluble and chemically reactive than the parent PAH, thus increasing their potential for mineralization by indigenous soil bacteria (Cerniglia, 1997). Ligninolytic fungi, such as Phanerochaete chrysosporium and Trametes versicolor, use extracellular enzymes involved in lignin degradation, such as lignin peroxidase, manganese peroxidase, and other H2O2-producing peroxidases or laccases, to degrade PAHs (Bezalel et al., 1997; Bumpus, 1989; Hammel et al., 1992). These enzymes oxidize a wide range of organic compounds in a nonspecific radical-based reaction. This results in the production of quinones and acids, rather than dihydrodiols. Prokaryotic and eukaryotic algae have also been reported to oxidize PAHs from hydroxylated intermediates (Fig. 2.2). Cyanobacteria appear to employ monooxygenases for the oxidation of low molecular weight
38
Evelyn Doyle et al.
PAHs, producing metabolites similar to those of mammals and fungi. In contrast, the production of cis-dihydrodiols by the eukaryotic alga Selenastrum capricornutum growing on benzo[a]pyrene indicated a dioxygenase mode of attack, similar to heterotrophic prokaryotes (Narro et al., 1992a,b; Schoeny et al., 1988; Warshawsky et al., 1988, 1995). PAH degradation is most extensive under aerobic conditions, but is known to occur to some extent in anaerobic environments (Bianchin et al., 2006; Coates et al., 2002; Davidova et al., 2007; Hayes and Lovley, 2002; Spormann and Widdel, 2000; Zhang et al., 2000). Nitrate and sulphate have been reported as alternative electron acceptors (Heider et al., 1998; Holliger and Zehnder, 1996). Although pathways for the anaerobic degradation of naphthalene and phenanthrene have been proposed, details of the mechanisms involved remain to be elucidated (Annweiler et al., 2002). Metabolism of PAHs by pure cultures has provided information on the types and diversity of metabolic pathways. Nevertheless, it is important to appreciate how this knowledge transfers to microbial processes degrading PAHs in real environments such as polluted soils, sediments, and waters. Biodegradatory studies are now focused on elucidating how microbially mediated degradation works at an environmental level.
B. Culture-independent analysis In contaminated environments, microorganisms exist amongst complex communities. Nutrient availability can be diverse, with a complexity of available carbon and other nutrient sources that may be used in preference to PAHs. Additionally, most environments would be considered oligotrophic (Hamer, 1992). Although culture-based studies have indicated the types of PAH metabolism that take place, the environmental fate of PAHs is not well understood. A complicating factor in understanding microbial mediation of PAH metabolism in the environment is that less than 1% of microorganisms are culturable (Torsvik and Ovreas, 2002), so that studies carried out on isolates do not necessarily reflect environmental microbial activity. Recent advances in molecular techniques have extended our ability to profile microbial communities in natural environments using cultureindependent methods (Liu et al., 1997; Mills et al., 2003; Torsvik and Ovreas, 2002). Such approaches have focused either on describing microbial diversity and community structure, or on elucidating gene activity involved in PAH degradation. Most attention, to date, has been paid to elucidating microbial community structures utilizing molecular analysis of the rRNA gene complex or other phylogenetically separable genes. After extraction of environmental nucleic acids, specific primers are selected to amplify rRNA gene diversity by PCR, prior to either cloning and sequencing or the use of fingerprint techniques such as denaturing
Microbial PAH Degradation
39
gradient gel electrophoresis (DGGE), automated ribosomal intergenic spacer analysis (ARISA), and terminal restriction fragment length polymorphism (TRFLP). These approaches generate both phylogenetic information and profiles of overall community structure. For a fuller view of the techniques typically used, the reader is referred to Hugenholtz et al., 1998; Konstantinidis and Tiedje, 2004; Torsvik et al., 1998; Xu, 2006. The challenge for microbial ecologists is to link microbial diversity to individual functional components of PAH metabolism in environments. Microbial communities have been examined in a range of PAH contaminated environments including soil, rhizosphere, water, sediments, anoxic sediments, and bioreactors (Table 2.4). Most studies, to date, have been concerned with bacterial communities from aerobic environments, although the effects of PAHs on fungal (Salvo et al., 2005), archaeal (Chang et al., 2005), and protozoan community structures (Lara et al., 2007) have also been reported. There are many reports of shifts in microbial community structure occurring during PAH degradation (Grant et al., 2007; Vinas et al., 2005). Bacterial community composition in a creosote-contaminated site was found to be correlated to the type of PAH present rather than with PAH concentration (Muckian et al., 2007). For example, community structure in the presence of naphthalene (2-ring) was quite distinct from that in soil containing multicomponent mixtures of PAHs (2-, 3-, and 4-ring). Plant roots have also been found to influence PAH degradation, with the highest levels of degradation being observed closest to roots; community structure near to root surfaces was quite different from zones further away (Corgie et al., 2004, 2006a). Using a PLFA (phospholipid fatty acid analysis) approach rather than a molecular approach, Yang et al. (2007) observed that bacterial PFLA patterns varied in PAH contaminated soils in the presence of different vegetation and over the growing period, whilst Parrish et al. (2005) observed differences over the growing period. Comparison of culture-based and molecular diversity estimates is informative. The culturable component of bacterial communities from PAH contaminated environments tends to belong to a limited number of taxonomic groups and is generally dominated by Sphingomonas and Mycobacterium spp. (Bastiaens et al., 2000; Johnsen et al., 2005, 2007; Leys et al., 2005; Mueller et al., 1990). It has been suggested that Sphingomonas spp. are associated with the initial degradation of high concentrations of low molecular weight PAHs, whereas Mycobacterium spp. are involved in degradation of less available higher molecular weight PAHs (Friedrich et al., 2000). PLFA analysis of a creosote contaminated site indicated that those associated with Gram negative bacteria were the only ones not negatively correlated with PAH concentration (To¨rneman et al., 2008). Sphingomonas spp. have been identified in a variety of PAH contaminated environments using genus specific primers (Leys et al., 2004), but interestingly, inoculation of contaminated
40 TABLE 2.4 Molecular based studies used to examine microbial communities in PAH contaminated environments Environment
Technique(s) used
Targeted groups
Reference
PAH contaminated soils
DGGE
Bacteria, Eubacteria, and Mycobacteria
Functional gene (phnAc) diversity Quantitative real time PCR of nahAc gene Culture-based analysis and 18S rDNA clone library Competitive PCR of nahAc and phn genes DGGE and 16S rDNA clone libraries TGGE
Naphthalene degrading bacteria Naphthalene degraders and Bacteria Protozoa
Vinas et al. (2005), Uyttebroek et al. (2007b) Wilson et al. (2003)
Aged PAH contaminated soils
Fertilized and slurried aged PAH contaminated soil Batch and biofilm enrichment from a PAH contaminated soil
DNA-SIP combined with DGGE and 16S rDNA clone libraries Culture-based analysis, DNA and cDNA clone libraries, functional gene diversity
Bacteria degrading low molecular weight PAHs Bacteria, Sphingomonas and Mycobacteria spp. Mycobacteria
Park and Crowley (2006) Lara et al. (2007) Laurie and Lloyd-Jones (2000) Uyttebroek et al. (2007a)
Pyrene degrading bacteria
Cheung and Kinkle (2001) Jones et al. (2007)
Bacteria and fungi
Stach and Burns (2002)
Bioreactor treating soil and groundwater from a gasworks site Bioreactor treating PAH contaminated soil
Naphthalene, phenanthrene, and pyrene enrichments from PAH contaminated soil PAH contaminated soil inoculated with PAH degrading bacteria Pristine soil amended with bioremediated soil Rhizosphere of PAH contaminated soil
DGGE (16S rRNA and NDO genes)
Bacteria
Ferguson et al. (2007)
DNA-SIP combined with DGGE, 16S rDNA clone libraries, and quantitative PCR with group specific primers DGGE, ARDRA, and functional gene analysis
Bacteria
Singleton et al. (2005, 2006, 2007)
PAH dioxygenase population
Ni Chadhain et al. (2006)
DGGE Functional gene (nahAc) analysis
Bacteria
Real time PCR of pdo1 gene
Mycobacteria
Coppotelli et al. (2007), Cunliffe and Kertesz (2006), Piskonen et al. (2005) Johnsen et al. (2007)
Phospholipid fatty acid analyis (PLFA) TGGE, DNA and RNA
Mycorrhizae
Joner et al. (2001)
Bacteria
Corgie et al. (2004, 2006a, 2006b) (continued)
41
42 TABLE 2.4 (continued) Environment
PAH contaminated urban mangrove sites PAH contaminated sediments
Technique(s) used
Targeted groups
Reference
Functional gene (alkB, ndoB and xylE) analysis and DGGE DGGE using ndo primers
Bacteria
Nakai et al. (1983), Siciliano et al. (2002)
Bacteria
Gomes et al. (2007)
Bacteria and Archaea Bacteria
Chang et al. (2005) Edlund and Jansson (2006) Hilyard et al. (2008), Dionisi et al. (2004), Ghiorse et al. (1995), Langworthy et al. (1998). Rogers et al. (2007)
16S rDNA clone libraries BrdU Immunocapture and T-RFLP DGGE Functional gene (nagAc, nahAc, nahR, alkB, nahA, nahH, tolC1/C2) diversity
FISH using group specific probes
Groundwater from a coal tar waste contaminated site
RT-PCR of nahAc sequences
Naphthalene degrading bacteria
Archaea, a, b, and g Proteobacteria, sulphate reducing bacteria and specific bacterial groups Naphthalene degrading bacteria
Wilson et al. (1999)
Treatment plant treating PAH contaminated water Open lagoons containing ship bilge wastes Anaerobic methanogenic enrichments of a wastewater sludge
Functional gene (nahAc, phnAc, C12O, and C23O) analysis Functional gene (nahAc) analysis FISH
Bacteria degrading low molecular weight PAHs
Wang et al. (2007)
Naphthalene degrading bacteria Bacteria, Archaea, and Methanobacteriales
Olivera et al. (2003) Christensen et al. (2004)
43
44
Evelyn Doyle et al.
soil with Sphingomonas spp. did not stimulate PAH degradation (Coppotelli et al., 2007; Cunliffe and Kertesz, 2006). Most Mycobacterium spp. isolated from PAH contaminated environments have been placed in the phylogenetic branch of the fast growing mycobacteria. These bacteria have been reported to metabolize high molecular weight PAHs such as pyrene and benzo[a]pyrene in culture (Heitkamp et al., 1988; Kim et al., 2005; Uyttebroek et al., 2007a) and are adapted to oligotrophy (Wick et al., 2002, 2003). The fast growing mycobacteria appear to be involved in the degradation of sorbed PAHs, which has been attributed to their mycolic-rich cell walls that allow them to attach to PAH enriched soil particles (Barry et al., 1998; Cheung and Kinkle, 2001). Amplification of DNA from soil samples containing differing levels of PAH contamination with mycobacteria-specific primers has revealed the presence of fast growing mycobacteria in several PAH contaminated soils, whereas these organisms could not be detected in nonpolluted environments (Leys et al., 2005). Using a similar approach, Cheung and Kinkle (2001) detected novel strains of these bacteria in petroleum-contaminated soils but reported a reduction in diversity, with less mycobacterial phylotypes detected in PAH contaminated soils (Cheung and Kinkle, 2005). A combination of MPN-PCR and FISH revealed that Mycobacterium spp. represented a greater proportion of the community in soil fractions where maximum PAH degradation occurred (Uyttebroek et al., 2006). Addition of a previously bioremediated soil (whose culturable portion was dominated by mycobacteria) to a pristine soil artificially contaminated with PAHs had little effect on PAH degradation ( Johnsen et al., 2007). Although a number of bacterial groups appear to be associated with PAH contamination, their function in PAH metabolism in situ remains unclear. By feeding a microbial community a 13C labeled substrate and subsequently isolating the heavy labeled fraction of DNA or RNA, organisms involved in the transformation of the substrate can potentially be identified using DNA-stable isotope probing (DNA-SIP) or RNA-SIP, respectively (Manefield et al., 2004). In three separate DNA-SIP based examinations of PAH contaminated soil, Mycobacterium spp. were found not to be associated with PAH degradation ( Jones et al., 2007; Singleton et al., 2005, 2007). Naphthalene and salicylate-degrading communities were composed mainly of sequences belonging to the Pseudomonas and Ralstonia genera, whereas phenanthrene-degrading communities were dominated by sequences related to the genus Acidovorax (Singleton et al., 2005). Similarly, mycobacteria were not identified as significant pyrene degraders during DNA-SIP of aged PAH-contaminated soil ( Jones et al., 2007) or in a bioreactor treating contaminated soil (Singleton et al., 2006). The main pyrene degraders in this bioreactor experiment appeared to be uncultivated low-abundance b and g proteobacteria, not previously
Microbial PAH Degradation
45
associated with pyrene degradation, although nondetection of Mycobacterium spp. may have been due to an enrichment bias introduced by continuous mixing within the bioreactor that did not favor biofilm-forming bacteria such as mycobacteria. Although SIP methods are very attractive in potentially linking PAH degradation to specific diversity, some caution is required in interpretation of results. Organisms identified by DNA/ RNA-SIP may not necessarily be directly involved in PAH degradation but may have incorporated 13C from labeled PAH as a result of crossfeeding (McDonald et al., 2005). Additionally, SIP approaches may introduce selection biases for organisms capable of utilizing test substrates, and often expose communities to substrate concentrations higher than those that exist in situ ( Jones et al., 2007).
C. Marker genes Community analysis using specific catabolic genes can be used to study the dynamics of those communities that may potentially be responsible for PAH degradation. In pure culture systems, initial oxidation of PAH and subsequent catechol cleavage are key steps in PAH metabolism and as a result, genes encoding enzymes catalyzing these steps have been proposed as indicators of in situ PAH degradation (Hayes and Lovley, 2002). Table 2.5 lists some of the genes used as indicators of PAH degradation. The genes encoding naphthalene biodegradation in Pseudomonas spp. are plasmid encoded and located in three operons; the first operon encodes the upper pathway enzymes that transform naphthalene to salicylate; the second encodes the enzymes of the lower pathway which produce TCA intermediates via catechol formation; and the final operon encodes a regulatory protein (Simon et al., 1993; Yen and Gunsalus, 1982, 1985). The so-called nah genes that encode the alpha subunit of the iron– sulphur component of naphthalene dioxygenase (NDO) from strains of pseudomonads are the most widely employed catabolic markers for communities associated with PAH degradation. NDO is a multicomponent dioxygenase, typically consisting of a ferredoxin, a reductase, and an iron–sulphur protein which catalyzes the initial oxidation of PAHs. The iron–sulphur protein is composed of an alpha subunit containing the active site of the enzyme and a smaller beta subunit. The alpha subunit of the iron–sulphur protein of this enzyme is encoded by the nahAc gene (Gibson and Parales, 2000; Simon et al., 1993; Yen et al., 1991). This gene has been detected in a range of environments and higher frequencies have been reported in polluted sites (Ghiorse et al., 1995; Langworthy et al., 1998; Laurie and Lloyd-Jones, 2000; Tuomi et al., 2004; Wilson et al., 2003). Copy number of nahAc increased over a thousand-fold in a soil exposed to naphthalene, whereas the amount of 16s rRNA remained relatively stable (Moser and Stahl, 2001; Park and Crowley, 2006).
46
TABLE 2.5
Genes used as indicators of potential PAH degrading communities
Gene (nah-like genes)
nah nahAc nahAb ndo pah dox phn phnAc
dnt phd nag nid pdo nar
Protein encoded
Napthalene dioxygenase a-subunit of naphthalene dioxygenase Ferrodoxin component of naphthalene dioxygenase Naphthalene dioxygenase Naphthalene/phenanthrene dioxygenase Naphthalene dioxygenase Phenanthrene dioxygenase a-subunit of phenanthrene dioxygenase 2,4-dinitrotoluene dioxygenase Phenanthrene dioxygenase Naphthalene dioxygenase PAH ring cleaving dioxygenase Ring hydroxylating dioxygenase Naphthalene dioxygenase
Organism
Initial dioxygenases Pseudomonas putida strain G7, P. putida NCIB 9816-4
Reference
Eaton (1994), Simon et al. (1993)
P. putida NCIB 9816-4 Pseudomonas sp. OU582
Kurkela et al. (1988) Takizawa et al. (1994)
Pseudomonas sp. C18 Burkholderia sp. strain R007
Denome et al. (1993) Laurie and Lloyd–Jones (1999)
Burkholderia sp. strain DNT
Suen et al. (1996)
Nocardioides sp. strain KP7 Ralstonia sp. strain U2 Comamonas testosteroni GZ 39 and GZ42 Mycobacterium sp. strain PYR-1
Saito et al. (1999) Fuenmayor et al. (1998), Goyal and Zylstra (1997) Khan et al. (2001)
Mycobacterium sp. strain 6PY1
Krivobok et al. (2003)
Rhodococcus sp. strain NCIMB 12038
Kulakov et al. (2000)
bph
Biphenyl and phenanthrene dioxygenase
nahC/pahC
xyleE
1,2-dihydroxynaphthalene dioxygenase Catechol 2,3-dioxygenase Naphthalene chemotaxis protein Catechol 2,3-dioxygenase
alkB todC1/C2
Alkane monooxygenase Toluene dioxygenase
nahH nahY
Sphingomonas paucimobilis var. EPA505 Extradiol dioxygenases P. putida OUS82
Romine et al. (1999), Story et al. (2000)
P. putida mt-2
Habe and Omori (2003), Kiyohara et al. (1994) Ghosal et al. (1987) Grimm and Harwood (1999) Nakai et al. (1983)
Other enzymes Pseudomonas oleovorans ATCC 29347 P. putida F1
Beilen et al. (1994) Zylstra and Gibson (1989)
P. putida G7 P. putida G7
Genes are typically named according to the substrate that the bacterium initially degraded (nah for naphthalene, ndo for naphthalene dioxygenation (equivalent to nah), phe for phenanthrene, dox for dibenzothiophene, dnt for dinitrotoluene). Most strains were subsequently found to grow on a range of PAHs. nag is used to denote genes from organisms that degrade naphthalene via gentisate.
47
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Evelyn Doyle et al.
Initial investigations suggested that the nah gene was highly conserved among PAH degrading bacteria, but as genes encoding PAH metabolism in a wider range of bacteria were characterized it became clear that the nah-like genes from pseudomonads provided a limited view of the gene diversity involved in the initial oxidation of PAHs, even amongst culturable bacteria (Ahn et al., 1999; Dionisi et al., 2004). Only 45% of naphthalene degrading isolates could be detected using probes based on nah-like genes and these probes could only detect 15% of the strains that metabolized either phenanthrene or naphthalene (Laurie and Lloyd-Jones, 1999). Even PAH dioxygenases from pseudomonads appeared to differ significantly at the nucleic acid level while still expressing similar substrate specificities (Meyer et al., 1999). Genes encoding dioxygenases involved in the initial oxidation of low molecular weight PAHs from strains of Burkholderia, Comamonas, Ralstonia, Mycobacteria Rhodococcus, and Sphingomonas displayed little sequence homology with the archetypal pseudomonad nah genes (Allen et al., 1997; Brezna et al., 2003; Goyal and Zylstra, 1996; Khan et al., 2001; Pinyakong et al., 2003). Probes targeted to these genes have been used to screen a number of environments and results indicate that the nah-like genes are not typical of the diversity present. phn-Like genes, based on the gene encoding the initial oxidation of phenanthrene and naphthalene in Burkholderia sp. strain RP007, appeared to be of more ecological significance in New Zealand soils than nah-like genes (Laurie and Lloyd-Jones, 1999, 2000). Sequences typical of NDOs from Pseudomonas spp. and Comamonas spp. were detected in DNA extracted from a sequential reactive barrier treating groundwater from a former gas manufacturing plant, but no sequences representative of Rhodococci NDOs were observed (Ferguson et al., 2007). A number of novel extradiol dioxygenase sequences were observed in soil from PAH contaminated sites in Finland using a suite of primers targeted to genes encoding the catechol cleavage step (Sipila et al., 2006). Similarly, primers targeted to the alpha subunits of Group III ndo genes (which includes phn, nah, and several other ndo genes) retrieved mainly sequences representing novel genotypes from three urban mangrove sites (Gomes et al., 2007). Clone libraries, prepared from two contaminated and two pristine soils using a primer set targeted to the conserved amino acid motifs in ring hydroxylating dioxygenases, contained several novel dioxygenase gene fragments. Sequence analysis revealed that these environmental clones clustered into six distinct groups, only one of which included previously described ring hydroxylating dioxygenases (Yeates et al., 2000). Using primers targeting the conserved Rieske center rather than the catalytic domain of dioxygensases, different suites of genes were detected in soil microbial populations degrading a range of PAHs (Ni Chadhain et al., 2006).
Microbial PAH Degradation
49
PAH contaminated environments typically contain a mixture of low and high molecular weight PAHs. Although the degradation of high molecular weight PAHs is receiving more attention (Kanaly and Harayama, 2000), there is little information concerning the genes involved in degradation of these compounds. Degradation of complex substrates is typically mediated by extensive microbial diversity and designing molecular markers to profile degradative activity in such a community represents a significant challenge. Although a correlation generally exists between the relative abundance of biodegradative genes and the potential for pollutant degradation (Laurie and Lloyd-Jones, 2000; Meyer et al., 1999; Park and Crowley, 2006), monitoring gene expression (mRNA) in a microbial community in response to PAHs provides more meaningful information concerning the functioning of the community. Wilson et al. (1999) demonstrated that nahAc genes were actively transcribed in the groundwater from a site contaminated with coal tar. Sequences retrieved were related to dioxygenases from Pseudomonas putida NCIB 9816-4 and a Burkholderia sp. mRNA based analysis of complex environments is currently limited by difficulties in extracting sufficient mRNA and its short half-life (Pichard and Paul, 1993; Sayler et al., 2001; Sharma et al., 2007). Primer design is critical for any PCR-based analysis and it is clear that existing primers targeting PAH-degradative genes represent only a fraction of in situ gene diversity. If microbial populations are to be linked to PAH degradation in situ, information is needed regarding the genes expressed by the microbial community in response to PAHs. This should include not only previously uncharacterized degradative genes, but also genes not directly involved in PAH metabolism. The latter genes may provide additional insights into the overall response of the community to the perturbing influence and the factors controlling the rate and extent of degradation. The construction of a genomic DNA library from a contaminated environment is one potential approach to analyzing environmentally significant genes. Metagenomic analysis involves extracting total genomic DNA from an environmental sample, fragmenting and cloning it into a suitable vector, and transfecting a host bacterium (Rondon et al., 2000). The resulting library is then screened for functional or genetic diversity, allowing the genotype of microorganisms present in the environment to be assessed and providing information on organisms that cannot be cultured. Metagenomic technologies have been used to characterize entire ecological communities, albeit only in environments containing a low level of diversity (Crossman et al., 2004; Handelsman, 2004). Construction of a metagenomic library from soil has traditionally been considered impractical due to the large number of sequences present (Gans et al., 2005). However, the recent development of inexpensive high throughput
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Evelyn Doyle et al.
pyrosequencing may make the construction of metagenomic libraries from contaminated soil more feasible (Roesch et al., 2007). Although low abundance genomes involved in degradation may be under-represented in a metagenomic library (Eyers et al., 2004), a functional screen would provide significantly more information regarding the true diversity of genes involved in PAH degradation than pure culture studies. Sequence information obtained from genomic analysis can be used to design DNA microarrays. A DNA microarray typically contains thousands of phylogenetic or functional sequences spotted in a grid on a slide. DNA or mRNA is extracted from samples labeled with fluorescent molecules and hybridized to target DNA on the slide. The resulting hybridization profile is then visualized and digitalized for quantitative analysis. Microarrays based on sequence information retrieved from culturable organisms have been used to monitor genes involved in 2,4dichlorophenoxyacetic acid (2,4-D) degradation in environmental samples (Dennis et al., 2003). Microarrays containing functional and phylogenetic sequences relevant to PAH degradation would have considerable application in bioremediation, allowing microbial structure, function, and dynamics in a contaminated site to be assessed.
IV. BIOREMEDIATION OF PAH CONTAMINATED ENVIRONMENTS Bioremediation has been used with varying degrees of success to treat PAH contaminated sites. Bioremediation strategies can involve natural attenuation, bioaugmentation, or biostimulation and can take place in situ or ex situ (Mueller et al., 1996). Natural attenuation relies solely on the capacity of indigenous microbial communities present to remove contaminating chemicals and may be slow if biodegradation is limited by one or more environmental factors (e.g., lack of nutrients, Fig. 2.1). Although addition of inoculants has been reported in some instances to enhance PAH degradation in soil (Garon et al., 2004; Zheng and Obbard, 2002), bioaugmentation has not been successfully demonstrated for large scale remediation of PAHs ( Johnsen et al., 2005). Microorganisms capable of degrading PAHs exist in most environments, and it is thus not surprising that most success to date has been achieved with strategies that stimulate the biodegradative capacity of indigenous microbial communities. PAH concentrations in soil have been successfully reduced using landfarming, composting, and nutrient supplementation (Guerin, 1999; Hansen et al., 2004; Kastner and Mahro, 1996; Kastner et al., 1998; Vinas et al., 2005). Landfarming is considered an acceptable approach for the remediation of contaminated wood treatment sites (US EPA, 2004). This technology can be carried out in situ using traditional agricultural practices
Microbial PAH Degradation
51
such as tilling and fertilizer application which increases aeration, mixing, and nutrient concentration in the soil. Greater success has been achieved using ex situ treatments such as land treatment units (LTUs), composting, and bioreactors. Although these approaches are less cost effective and require excavation of the contaminated materials, they allow greater monitoring and control of environmental parameters and can still take place on-site. 2- and 3-ring PAHs were almost completely removed from a creosote contaminated soil treated in an LTU using a combination of tilling, fertilization with a controlled release of N-P-K fertilizer, and irrigation to maintain soil moisture content at 18% (Guerin, 1999). Higher molecular weight PAHs were not removed to the same extent, <35% of 6-ring PAHs being degraded. Composting of PAH contaminated soil with various wastes including spent mushroom compost, paper, grass, alfalfa, and food waste has been demonstrated to effectively remove PAHs, both as a solid phase treatment and in bioreactors ( Joyce et al., 1998; Lau et al., 2003) In general, the rate and extent of PAH degradation is greater in bioreactors as process parameters such as pH, temperature, nutrient levels, and aeration can be more easily controlled (Garon et al., 2004; Woo et al., 2004). Bioreactors also provide the opportunity to add surfactants or inoculants, if appropriate (Kim et al., 2001; Zheng and Obbard, 2002). Although bioremediation technologies have been successfully applied for PAH removal, processes are often unpredictable and unreliable, and little is understood concerning the complex interrelationships between microbial communities and the associated effects of influencing environmental variables.
A. Factors affecting bioremediation Typically, microbial communities exposed to PAHs require time to adapt before degradation occurs (Barkay et al., 1995). This acclimation period is of considerable public health and ecological significance as it increases the length of time susceptible species are exposed. If, for example, PAHs have leached into watercourses, wide-scale dissemination may occur from the original source. The duration of the acclimation period depends on a number of environmental variables such as contaminant concentration, bioavailability, pH, temperature, levels of nitrogen and phosphate present, aeration status, and prior exposure of microbial communities to PAHs (Alexander, 1999; Spain and Van Veld, 1983). Heterogeneous distribution of PAHs in soil combined with their absorption to organic matter and low levels of diffusibility, limits bacterial access to PAHs as substrates (Bosma et al., 1997; Johnsen et al., 2005). Many bacteria produce biosurfactants when grown on hydrocarbons and these can increase PAH solubility (Oberbremer et al., 1990; Van Dyke et al., 1993).
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For example, a rhamnolipid producing P.aeroginosa strain that did not degrade PAHs, increased the rate of phenanthrene degradation by a PAH metabolizing pseudomonad (Arino et al., 1998). Although surfactant production appears to be an obvious means of overcoming limited bioavailability, there is often no correlation observed between PAH degradation and surfactant production in pure culture (Willumsen and Karlson, 1996). Chemical and biological surfactants have been added to contaminated soils to increase PAH availability, but success has been mixed and in some cases surfactants have inhibited degradation (Laha and Luthy, 1991). Other microbial phenotypes suggested to facilitate growth on hydrophobic compounds include enhanced cell surface hydrophobicity, biofilm formation, motility, and chemotaxis ( Johnsen et al., 2005; Parales and Harwood, 2002). PAH degradation is generally an aerobic process, although anaerobic degradation has been reported (Bianchin et al., 2006; Chang et al., 2005; Holliger and Zehnder, 1996; Zhang et al., 2000). Oxygen levels in PAH contaminated environments such as soils and sediments are typically well below the levels required for aerobic transformation of PAHs. Increasing the aeration status of such environments via tilling of soil, addition of materials that increase the interparticle space within the soil matrix, direct injection of oxygen (sparging), or introduction of oxygen generating species such as H2O2 have been shown to increase both the rate and often the extent of PAH degradation (Guerin, 1999; Guerin and Boyd, 1992; Kaplan and Kitts, 2004). The rate of PAH degradation is generally faster in soil that has a history of PAH contamination. A study by Johnsen and Karlson in 2005 revealed that the rate of 14C-labeled pyrene and phenanthrene mineralization was inversely proportional to the PAH content of 13 different soils. 14 C-phenanthrene was removed from all soils tested including two pristine forest soils, but little mineralization of 14C pyrene was observed over 140 days in pristine soils. The dependence of phenanthrene and pyrene removal rates on previous exposure has also been reported in some UK soils (Macleod and Semple, 2006). PAH degradation in environments with no history of previous contamination may result from exposure to PAHs from natural sources such as biogenic synthesis (Grimalt et al., 2004), atmospheric deposition of PAHs from contaminated sites, or the presence of microorganisms that produce broad specificity enzymes such as laccases. In situ horizontal transfer of PAH metabolizing genes (nahAc and phnAC) has been reported between phylogenetically distinct bacteria, and this may also explain the PAH degradative capacity of communities with no known exposure to PAHs (Park and Crowley, 2006; Stuart-Keil et al., 1998; Wilson et al., 2003). Previous exposure of a microbial community to one PAH has frequently been reported to reduce the acclimation period for degradation of other PAHs (Bauer and Capone, 1988; Beckles et al., 1997).
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A Mycobacterium sp. isolated from a PAH enrichment of a contaminated river sediment degraded phenanthrene and pyrene following exposure to either compound (Molina et al., 1999), and 4- and 5-ring PAHs disappeared more rapidly from soils amended with complex mixtures of PAHs (Keck et al., 1989). In some instances it would appear that the acclimation period merely reflects the time taken for degrading populations to reach a high enough cell density to effect a detectable change. The density of phenanthrene and pyrene degraders was higher in soils previously exposed to these PAHs ( Johnsen and Karlson, 2005; Macleod and Semple, 2006). Any factor stimulating the growth of degrading populations (e.g., addition of nutrients, aeration, etc.) would thus affect degradation rates. For example, addition of phenanthrene increased the initial rate of fluoranthene degradation in soil, but a similar effect was observed if a biosurfactant was added instead of the 3-ring PAH (Hickey et al., 2007).
V. CONCLUSIONS There have been considerable advances in understanding PAH metabolism in pure culture and identifying microbial diversity in PAH contaminated sites. The real challenge now lies in trying to link these organisms to specific functions associated with in situ degradation, and use this information for the rational design of reliable bioremediation strategies. Technologies such as stable isotope probing, metagenomics, and microarrays offer potential in elucidating in situ microbial PAH degradation. Comparison of gene expression in contaminated and uncontaminated environments may reveal key processes associated with in situ microbial degradation and adaptation. This information can be used to develop functional and phylogenetic microarrays for the assessment of microbial diversity, degradative potential, and metabolic pathways likely to occur in contaminated sites. Genomic analysis may also assist in culturing previously unculturable PAH degrading organisms, allowing a deeper profiling of microbial activity at the metabolic level. Most studies to date have concentrated on organisms directly involved in PAH degradation and have generally ignored interactions with associated microflora; if factors controlling in situ PAH degradation are to be manipulated, these interactions must be understood. Although significant challenges still exist, bioremediation represents a competitive technology for PAH contaminated sites. Information regarding in situ microbial processes can only advance the application of this technology.
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CHAPTER
3 Acid Stress Responses in Listeria monocytogenes Sheila Ryan,† Colin Hill,*,† and Cormac G. M. Gahan*,†,‡,1
Contents
I. Introduction II. Listeriosis III. Acid Tolerance Response (ATR) and Cross Protection IV. Acid Resistance and Listerial Survival in Foods V. Acid Resistance and L. monocytogenes Pathogenesis VI. Listerial Mechanisms of Acid Resistance A. GAD system B. Arginine and agmatine deiminase systems C. F0F1-ATPase D. Macromolecular protection and repair E. Cell membrane changes F. Sigma B G. LisRK two-component regulatory system VII. Conclusion References
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* Alimentary Pharmabiotic Centre, University College Cork, Cork, Ireland { { 1
Department of Microbiology, University College Cork, Cork, Ireland School of Pharmacy, University College Cork, Cork, Ireland Corresponding author: Department of Microbiology, University College Cork, Cork, Ireland
Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00603-5
#
2008 Elsevier Inc. All rights reserved.
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I. INTRODUCTION The Gram positive intracellular pathogen Listeria monocytogenes is the causative agent of listeriosis, a potentially fatal foodborne infection that predominately affects pregnant women and those with underlying immunesuppression. It is significant that the pathogen is regularly exposed to low pH environments during the infectious cycle; in acidic foods, upon passage through the gastric barrier, and subsequently, upon entry to the host cell phagosome. The ability of L. monocytogenes to adapt to low pH environments therefore has the potential to significantly influence survival and growth in foods as well as subsequent pathogenesis. Furthermore, the adaptive response to low pH has the capacity to induce cross protection against other stresses including those encountered during intestinal growth (bile salts, elevated osmolarity). It is essential therefore to understand the molecular mechanisms that underpin acid adaptation, pH homeostasis, and stress-hardening in this organism in order to model and control growth of the pathogen in high risk foods and to predict the impact upon ability to cause disease. Specific mechanisms involved in maintenance of intracellular pH homeostasis during acid exposure include the glutamate decarboxylase (GAD) system, the arginine deiminase (ADI) system, the F0F1-ATPase, and general stress proteins. The regulatory networks governing control of these systems (including Sigma B and the two-component system LisRK) will also be discussed.
II. LISTERIOSIS The ubiquitous bacterium L. monocytogenes is the etiological agent of listeriosis, a rare but potentially fatal foodborne disease. The pathogen causes disease predominately in immunosuppressed individuals including those with HIV/AIDS and those undergoing immunosuppressive therapies giving rise to meningitis and meningoencephalitis. L. monocytogenes also has a propensity to infect pregnant women resulting in infection of the fetus and spontaneous miscarriage or serious neonatal infection in the newborn infant (McCabe-Sellers and Beattie, 2004; McLauchlin et al., 2004; Spyrou et al., 1997; Thom and Forrest, 2006). The pathogen is capable of host cell invasion and intracellular growth and therefore has the ability to cross a number of host barriers to infection, namely the gastrointestinal barrier, the blood-brain barrier, and the placental barrier. Furthermore, although relatively infrequent, cases of febrile gastrointestinal disease suffered by otherwise healthy individuals have also been attributed to infection by Listeria (Ooi and Lorber, 2005; Schlech et al., 2005; Sim et al., 2002).
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The types of foods associated with transmission of listeriosis include a number of ready-to-eat (RTE) foods including deli meats, hotdogs, soft cheeses, raw milk, and raw vegetables (Hof, 2003; Kathariou, 2002; Tompkin, 2002). The disease may be spread through large common-source epidemics but most commonly occurs as spontaneous independent cases where the source of infection is unclear (Gahan and Hill, 2005; VazquezBoland et al., 2001). Significantly, the mortality rate for L. monocytogenes infections approaches 30% (Ramaswamy et al., 2007). The serious nature of the infection has resulted in heightened vigilance by the food industry to prevent infections and has led to significant research efforts to identify factors which may influence foodborne growth of the pathogen and subsequent pathogenesis. The molecular analysis of the pathogen has been aided in recent years by the availability of genome sequences of a number of typed isolates of L. monocytogenes, including a number of serotype 4b strains associated with large epidemic outbreaks of listeriosis (Doumith et al., 2004; Glaser et al., 2001; Nelson et al., 2004).
III. ACID TOLERANCE RESPONSE (ATR) AND CROSS PROTECTION It has been observed that exposure to sub-lethal levels of one stress can result in induction of tolerance to the same or other stresses of greater magnitude (Lou and Yousef, 1997). The acid tolerance response (ATR) involves the acquisition of enhanced acid tolerance following a brief exposure to mildly acidic growth conditions (Koutsoumanis et al., 2003) and has been welldocumented in many foodborne bacteria, including Salmonella spp. (Foster, 1993; Foster and Hall, 1990; Lee et al., 1995), S. flexneri (Small et al., 1994), V. cholerae (Merrell and Camilli, 1999), and Listeria (Cataldo et al., 2007; Davis et al., 1996; O’Driscoll et al., 1996). Acid adaptation, which is normally transient, has become significant with regard to food safety, because within certain foods it can enhance bacterial survival (Cataldo et al., 2007; Gahan et al., 1996; Leyer and Johnson, 1992; Stopforth et al., 2007). Work aimed at uncovering the molecular basis of the ATR is outlined below. Acid-adapted cultures of pathogens have been shown to exhibit crossprotection against other food-related stresses such as heat and irradiation (Samelis et al., 2003). Indeed, it has been found that many stressors, including those used as preservative methods, such as heat, salt, and low pH, simultaneously induce cross-protection against elevated levels of other stresses, thereby enabling bacteria to survive otherwise lethal challenges (Casey and Condon, 2002; Flahaut et al., 1996). The phenomenon of cross-protection or ‘‘stress hardening’’ is clearly seen in L. monocytogenes (Faleiro et al., 2003; O’Driscoll et al., 1996; Lou and Yousef, 1997; Skandamis et al., 2008). These effects are most likely mediated by
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the induction of global stress-response mechanisms, which confer simultaneous resistance to numerous stresses. In particular, several studies have shown that acid adaptation in L. monocytogenes confers resistance to heat, salt, ethanol, and crystal violet (O’Driscoll et al., 1996). We and others have previously shown that acid adaptation also induces enhanced resistance against bacteriocin activity, a phenomenon possibly linked to an alteration in the fatty acid composition of the membrane (Bonnet and Montville, 2005; van Schaik et al., 1999). Acid adaptation of listeriae has also been shown to engender cross-protection against in vivo-associated stresses such as bile (Begley et al., 2002).
IV. ACID RESISTANCE AND LISTERIAL SURVIVAL IN FOODS As outlined above, listeriosis is primarily transmitted through consumption of contaminated RTE foods (Hof, 2003; McLauchlin et al., 2004; Kathariou, 2002; Tompkin, 2002). In foods, contaminating listeriae frequently encounter sub-optimal environmental conditions and hence their survival relies on the ability to sense and respond to fluctuations in their surroundings. There is great interest in modeling the parameters affecting L. monocytogenes growth in foods as recent EU regulations (EC/2073/2005) permit a low level of listerial contamination (100 CFU/g) in RTE products provided that the food matrix does not support growth of the pathogen over the shelf-life of the product. The difficulty in controlling listerial growth in foods is compounded by the fact that L. monocytogenes is a relatively hardy organism. Analysis of the cardinal temperatures for bacterial proliferation indicates that growth occurs between 1.7 and 45.1 C under experimental conditions (Membre et al., 2005). The bacterium can also proliferate at highly elevated salt concentrations (up to 10% NaCl; Sleator et al., 2003). Significantly, the bacterium has also been observed to grow at minimal pH values of approximately 4.3 in HCl-acidified media (George et al., 1988; Tienungoon et al., 2000), although lower values have also been noted (Koutsoumanis and Sofos, 2005). Modeling growth limits in foods is extremely complex; however, as a number of other factors (inoculum size, bacterial growth phase, stress hardening, and nutrient availability) will influence bacterial growth in these environments (Koutsoumanis and Sofos, 2005; Skandamis et al., 2008). The ability to modulate metabolic processes in response to stress has the potential to influence survival of pathogens in acidic foods. Thus the propensity for listerial adaptation to low pH conditions (through the ATR) may have implications for food processors. In this context the ‘‘prior history’’ of contaminating bacteria may influence their subsequent survival in the food matrix through ‘‘stress hardening’’ (Lou and Yousef, 1997). We have previously demonstrated that Listeria cells undergoing an ATR display significantly enhanced survival during storage of low pH foods (cottage cheese,
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yoghurt, cheddar cheese, and salad dressing; Gahan et al., 1996). This has recently been extended to Italian-style soft cheeses along with the observation that nonadapted cells become acid adapted during storage of certain cheeses (Cataldo et al., 2007). However, for a number of other food processes and specific food environments acid adaptation did not influence subsequent bacterial survival (Foley et al., 2005; Formato et al., 2007).
V. ACID RESISTANCE AND L. monocytogenes PATHOGENESIS The ability of many pathogens to adapt to and subsequently survive harsh environmental challenges has a direct association with their potential to cause disease. The acid barrier of the stomach is the initial host defence system which must be breached by enteric pathogens in order to subsequently colonize the human host (Audia et al., 2001). The mean stomach pH under fasting conditions in healthy volunteers is approximately 2, a pH that can quickly kill most microorganisms including L. monocytogenes (Audia et al., 2001; Richard and Foster, 2004; Smith, 2003). Inherently acidresistant organisms such as E. coli O157 strains have a propensity to survive well in the stomach environment and therefore have low predicted infectious doses (approximately 1000 CFU; Diez-Gonzalez and Karaibrahimoglu, 2004). Other organisms such as V. cholerae will not survive well in the gastric environment unless they are pre-adapted (Merrell et al., 2002). The infectious dose of L. monocytogenes is considered to be between 106 and 109 CFU, but is very much dependent upon the nature of the food matrix and host susceptibility (FAO/WHO, 2004; FDA/FSIS, 2003). It is also likely that preadaptation and the physiological status of the bacterium will influence infection by L. monocytogenes as outlined below. The importance of maintaining an acidic gastric barrier to foodborne has been highlighted by a number of studies investigating the virulence of pathogens in animal models which have been treated with antacids. Buffering of murine stomach acidity is clearly associated with a significant reduction in the infectious dose of Salmonella species (Bearson et al., 1997; Riley et al., 1984). Similarly it was found that buffering of stomach acidity in neutropenic mice via administration of sodium bicarbonate solution prior to intragastric (i.g.) inoculation with L. monocytogenes EGD resulted in a significant enhancement in disease severity (Czuprynski and Faith, 2002). It has also been reported that a reduction in gastric acid production following treatment with the H2-receptor antagonist cimetidine increases the severity of gastrointestinal listeriosis in experimentally inoculated rats, as well as lowering the dose of L. monocytogenes necessary to induce an invasive infection (102 vs 106 CFU for control animals; Schlech, 1993).
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A number of retrospective studies have linked the use of acidsuppressive agents such as proton pump inhibitors and H2-receptor antagonists to an increased likelihood of listeriosis in humans (Cobb et al., 1996; Schuchat et al., 1991). In a food-borne outbreak of hospitalacquired listeriosis in Boston hospitals, patients receiving antacids or H2antagonists were found to be more likely than control patients to be infected with L. monocytogenes (Ho et al., 1986). Furthermore, in a study by Cobb et al. (1996), it was noted that there was an increased prevalence of L. monocytogenes fecal carriage documented in female patients receiving long-term treatment with H2-antagonists (carriage rate of 20% vs 2.1% for control patients). These data suggest that gastric acid is bactericidal to L. monocytogenes and that drugs that inhibit or neutralize acid produced in the stomach increase the susceptibility of individuals to infection by this organism (Smith, 2003). In addition, bacteria with impaired stress responses appear to be less virulent than their fully functional counterparts. Various mutations that confer acid sensitivity have been found to attenuate S. typhimurium infection (Bearson et al., 1997). Similarly Marron et al. (1997) identified a mutant of L. monocytogenes LO28 which is incapable of inducing an ATR and displays reduced virulence potential in mice during systemic infection, suggesting that the ATR contributes in part to the in vivo survival of L. monocytogenes. Saklani-Jusforgues et al. (2000) have shown that prior acid adaptation correlates with increased translocation rates of bacteria to mesenteric lymph nodes in mice inoculated intragastrically. Independent studies also show that acid-adapted or acid-resistant mutant strains of L. monocytogenes are more invasive in vitro (Conte et al., 2000, 2002) and virulent in vivo (O’ Driscoll et al., 1996). Whilst the precise locations of the mutations in these acid tolerant mutants have not been identified, their increased pathogenicity may be due to the upregulation of genes involved in pathogenesis. Low pH is an important signal to foodborne pathogens communicating that the bacterium has entered a potential host environment, and triggering the induction of molecular systems which are associated with bacterial virulence (Alpuche Aranda et al., 1992; Audia et al., 2001). It is significant that Listeriolysin O (LLO), a pore-forming toxin that facilitates phagosomal escape by Listeria (Portnoy et al., 1992), is distinct from related proteins due to its acidic pH optimum for phagosomal disruption (Kayal and Charbit, 2006). This listerial protein is irreversibly denatured at neutral pH (Schuerch et al., 2005) and only functions at low pH values (Kayal and Charbit, 2006). Furthermore, LLO activity is triggered in vivo by a lowering of the pH of the phagosome following cellular infection (Beauregard et al., 1997). Therefore, it appears that Listeria has developed a phenotype which not only copes with stressful in vivo environments but also is partially dependent on exposure to such conditions.
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Researchers have also examined the possibility that acid adaptation in foods may influence survival of gastric acid. It was found that cultures grown in frankfurters which had been treated with acidic antimicrobials showed increased subsequent resistance to the lethal effects of simulated gastric fluid following prolonged storage (Stopforth et al., 2005). Furthermore, studies have shown that prior exposure of L. monocytogenes to frankfurter exudate (Wonderling et al., 2004) and turkey meat (Peterson et al., 2007) also results in enhanced resistance to simulated gastric fluid.
VI. LISTERIAL MECHANISMS OF ACID RESISTANCE A. GAD system The GAD system provides a mechanism for maintaining pH homeostasis in a number of bacterial genera. The GAD enzyme, usually encoded by gadA or gadB, irreversibly decarboxylates the acidic intracellular substrate glutamate, producing the neutral compound g-aminobutyrate (GABA). An intracellular proton is consumed in the reaction, contributing to increased cytoplasmic pH. The GABA produced via the decarboxylation reaction is subsequently exchanged at the cell membrane for a molecule of glutamate by a glutamate:GABA antiporter, which is usually encoded by the gadC gene. ATP is also synthesized during the reaction, and this may contribute to pH homeostasis mediated by the F0F1-ATPase (Higuchi et al., 1997; see Fig. 3.1). It is striking that this system of acid resistance has primarily been identified in bacteria which transit the low pH of the gastric environment prior to causing foodborne disease. L. monocytogenes, S. flexneri, and E. coli have all been shown to require a functional GAD system for survival under low pH conditions (Cotter et al., 2001a,b; Smith et al., 1992; Waterman and Small, 1996). Furthermore, it has been shown in several studies that the level of GAD expression in bacteria correlates with the degree of acid tolerance (Cotter et al., 2001a; Yokoigawa et al., 2003), and it is likely that the presence of this system may facilitate passage through the GIT (Price et al., 2004). Interestingly, factors that are associated with the GI tract (low pH, anaerobiosis, hypo- and hyper-osmotic shock, bile salts, and chloride ions) have been shown to induce expression of the GAD system in a range of bacteria (Blankenhorn et al., 1999; Conte et al., 2002; De Biase et al., 1999; Jydegaard-Axelsen et al., 2004; Bron et al., 2006; Sanders et al., 1998). The GAD system of L. monocytogenes has been investigated in detail and found to play a major role in acid resistance. It appears that L. monocytogenes strains differ in their levels of intrinsic acid tolerance (Dykes and Moorhead, 2000), and strain-dependent variations in GAD
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Extracellular environment F0F1-ATPase: extrusion of protons H+
GAD system: consumption of intracellular protons Glutamate
H
+
2-CSs: sense and respond to H+ environmental changes
H+
GABA
ADI system: production of NH3, ATP Arginine
Ornithine
Arginine
Ornithine
Histidine kinase
P ATP
ADP+Pi
Glutamate
H+
GABA + CO2 Response regulator
NH3
Citrulline
Carbamoyl phosphate
Intracellular environment NH3 + CO2
σB: alternative sigma factor: controls global transcription of genes
Altered transcription results in increased production of proteins involved in acid resistance
Chaperonins: degradation of misfolded proteins
FIGURE 3.1 A graphical representation of selected acid resistance systems and mechanisms employed by the Gram-positive pathogen, Listeria monocytogenes.
expression correlate with survival in the hyperacidic environment of gastric fluid (Conte et al., 2002; Cotter et al., 2001a; Olier et al., 2004). Initial characterisation of the listerial system revealed that loss of the genes encoding a key GAD enzyme (now designated GadD2) and a glutamate transporter (now designated GadT2) had a significant effect on the ability of the cell to survive in low pH environments (>5 log reduction relative to the wild-type by 45 min post-exposure at pH 3.5; Cotter et al., 2001a). The GAD system was also shown to be a major component of the ATR as elimination of GAD enzymes significantly reduced acid adaptation in mutant strains. However, some inducible acid tolerance was demonstrated in these strains indicating that other mechanisms may also contribute to the ATR (Cotter et al., 2001a). Subsequent analysis of the genome of L. monocytogenes strain EGDe revealed that this strain has three GAD homologues (now designated gadD1, gadD2, and gadD3), and two antiporters associated with the first two characterized decarboxylase genes (gadT1 and gadT2) (Cotter et al., 2005; Glaser et al., 2001). The GAD genes are arranged in two operons (gadD1T1 and gadT2D2) that are some distance apart in the genome. gadD3 is located separately from these two operons and is monocistronically
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transcribed (Cotter et al., 2005; Joseph et al., 2006). Although the genes encoding the various enzymes are homologous to each other (the gadD1 and gadD2 genes share 68.2% identity), they have discrete functions in the listerial acid stress response. We determined that while GadD2 plays a major role in the ability of Listeria to survive low pH stress (Cotter et al., 2001a), GadD1 facilitates growth at mildly acidic pH values (Cotter et al., 2005). Significantly, the gadD1T1 operon is absent from certain strains of L. monocytogenes including epidemic strains of serotype 4b (Call et al., 2003; Nelson et al., 2004). Strains which naturally lack this operon were shown to exhibit poorer growth at moderately low pH than strains containing the gene system. Thus the presence of gadD1T1 is associated with an enhanced growth capacity at low pH and may influence distribution of certain strains in low pH foods and in the environment (Cotter et al., 2005). Whilst we have been unable to generate a clean deletion mutant in gadD3, a recent report demonstrated that an insertional mutant could be generated in this locus ( Joseph et al., 2006). That study showed that this locus is significantly upregulated during cellular infection and that the gadD3 mutant was impaired in intracellular growth ( Joseph et al., 2006). However, the role of GadD3 in acid tolerance remains to be established. In L. monocytogenes EGDe transcription of gadD1 occurs primarily in exponential phase, while transcription of gadT2D2 is comparatively higher and is induced upon entry to stationary phase and in response to acid induction (Conte et al., 2002; Cotter et al., 2001a). It appears that gadT1 and gadD3 are induced following acid adaptation (Wemekamp-Kamphuis et al., 2004), with gadD3 also being induced by entry into stationary phase and osmotic stress (Kazmierczak et al., 2003). In addition, gadT2D2 and gadD3 loci are regulated by the alternative sigma factor SigmaB (WemekampKamphuis et al., 2004). More recent work has indicated that the gadT2D2 operon is subject to a high degree of regulation, with transcriptional control exerted at multiple points by the regulators CtsR and sB (Hu et al., 2007). Further applied studies have demonstrated an important role for the GAD system in specific food models. Cotter et al. (2001b) demonstrated that the GAD system contributes significantly to survival of the pathogen in low pH foods such as fruit juices, yoghurts, salad cream, and mayonnaise. The authors demonstrated that glutamate was in excess in all of these foods, providing a substrate for the GAD system. In diluted skim milk, however, the addition of free glutamate significantly improved survival of the wild-type but not the GAD mutant strain (Cotter et al., 2001b). Jydegaard-Axelsen et al. (2004) have demonstrated that expression of the gad genes is increased when L. monocytogenes is grown in CO2, conditions known to reduce intracellular pH. Indeed, recent studies have demonstrated that mutation of specific genes within the GAD system can significantly impact upon survival of the pathogen in modified atmosphere-packaged foods (Francis et al., 2007).
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B. Arginine and agmatine deiminase systems Genomic analysis of L. monocytogenes EGDe reveals that this bacterium encodes a potential ADI system. This is a 3-enzyme pathway which has been associated with internal pH homeostasis of a number of bacterial genera including E. faecalis (Barcelona-Andres et al., 2002), streptococci (Degnan et al., 2000; Dong et al., 2002), L. plantarum (Spano et al., 2004), O. oeni (Tonon et al., 2001), and P. aeruginosa (Bourdineaud et al., 1993). Arginine is transported into the cell in exchange for a molecule of ornithine in an energy-independent fashion by an arginine–ornithine antiporter (encoded by arcD), while the enzymes of the pathway catabolize arginine ultimately to ornithine, ammonia, and carbon dioxide (Fig. 3.1). For each mole of arginine catabolized via the ADI system, 2 moles of ammonia (NH3) are produced, which subsequently combine with intracellular protons to produce ammonium (NH4þ) ions. This reaction increases the intracellular pH, thereby enabling survival in hostile environments which would otherwise be lethal for the cell. In addition, ATP is generated by the system and this can potentially be used to extrude protons via the F1F0-ATPase (Higuchi et al., 1997). We have recently created clean deletion mutants in the putative ADI pathway in L. monocytogenes and show that these mutants demonstrate reduced acid tolerance, suggesting that this system plays an active role in mediating pH homeostasis in Listeria (submitted for publication). Analysis of the listerial genome has also revealed the presence of genes encoding a homologous 3-enzyme pathway, the agmatine deiminase system, encoded by the agu genes. Agmatine, a decarboxylated derivative of arginine, is deiminated via this system, resulting in the generation of carbamoyl phosphate, putrescine, and ATP (Driessen et al., 1988). The system has been identified in several bacteria and has been characterized as being pH-inducible (Griswold et al., 2006; Llacer et al., 2007; Lucas et al., 2007). Further work is required to determine the functionality of the agmatine deiminase system in L. monocytogenes and to determine the regulatory networks that govern expression of these molecular systems.
C. F0F1-ATPase The F0F1-ATPase has a fundamental role in the maintenance of pH homeostasis. Functionally, this multisubunit enzyme is organized into two distinct, but physically linked domains; the catalytic portion (F1) is cytoplasmic and incorporates the a, B, g, d, and e subunits, while the integral membrane domain (F0), including the a, b, and c subunits, functions as a membranous channel for proton translocation (Sebald et al., 1982). The function of the cytoplasmic domain is to catalyze the synthesis
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of ATP when protons move from the outside of cells into the cytoplasm, through the membrane-bound domain, or to hydrolyze ATP when protons are moved out of the cell. The role of the F0F1-ATPase in organisms capable of oxidative phosphorylation is to synthesize ATP aerobically as a result of protons passing into the cell, and to generate a proton motive force (PMF) anaerobically, via the expulsion of protons. As a consequence of the latter mechanism, it is thought that the F0F1-ATPase can increase the intracellular pH in situations where it becomes acidified. For many bacteria, activity data demonstrate that a lowering of the intracellular pH is accompanied by induction of the F0F1-ATPase (Koebmann et al., 2000; Kuhnert and Quivey, 2003; Kullen and Klaenhammer, 1999), while in a number of bacterial species, including Lactobacillus acidophilus (Kullen and Klaenhammer, 1999), S. mutans (Kuhnert et al., 2004), and S. pneumoniae (MartinGaliano et al., 2001) transcription of the F0F1 operon is induced by exposure to low pH. The inherent acid tolerance of various bacteria is related both to the levels of F0F1-ATPase, as well as to the pH optima of the enzymes. It is clear that naturally acid tolerant organisms possess F0F1ATPases with lower pH optima (Sturr and Marquis, 1992; Martin-Galiano et al., 2001). Analysis of the role of the F0F1-ATPase in acid tolerance is limited by the fact that the system is essential for life in many bacterial species (Koebmann et al., 2000). We have been unable to create clean deletion of the genes encoding the system in L. monocytogenes (unpubished data). However, 2-dimensional gel electrophoresis studies have shown that the listerial F0F1-ATPase subunit is induced as a consequence of exposure to mild acid treatment (Phan-Thanh and Mahouin, 1999). Administration of DCCD, an ATPase inhibitor demonstrated that the ATPase is involved in acid tolerance and the ATR (Datta and Benjamin, 1997). In addition, we have created a partial insertion mutant in the F0F1-ATPase in L. monocytogenes that is not compromised in fitness. This mutant demonstrated that the F0F1-ATPase of L. monocytogenes is involved in the induction of the ATR in this bacterium (Cotter et al., 2000).
D. Macromolecular protection and repair Exposure to environmental stress can result in misfolding of proteins and damage to macromolecules such as DNA, and consequently bacteria require effective systems for repairing or disposing of damaged intracellular macromolecules (Matic et al., 2004). One of the most notable ways in which bacteria respond to damaged DNA is by use of nucleotide excision repair. This process is carried out by UvrA, UvrB, and UvrC proteins, which can recognize and cleave damaged DNA fragments as part of the ‘‘SOS response’’ to DNA damage. In S. mutans (Hanna et al., 2001) and
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L. helveticus (Cappa et al., 2005), it has been established that this process occurs in response to low pH adaptation. Using an in-frame deletion mutant of uvrA, Kim et al. (2006) have shown that this gene is also required for optimal growth of L. monocytogenes in acidic medium, with the DuvrA mutant exhibiting a significantly increased lag phase relative to the parent in low pH broth. In addition to the DNA damage induced by exposure to environmental stress, many proteins are synthesized abnormally. Chaperonins are a group of proteins which are responsible for cytoplasmic proteolysis or refolding of these erroneously synthesized proteins, and many of these proteins are induced following acid exposure in Listeria (Phan-Thanh and Mahouin, 1999). DnaK is a chaperonin which has been characterized as being necessary for optimal acid resistance in S. mutans (Lemos et al., 2007) and B. suis (Kohler et al., 2002) as well as L. monocytogenes. A Listeria mutant lacking a functional dnaK gene exhibits reduced survival at low pH values (Hanawa et al., 1999). Another chaperonin, GroESL is induced in response to acid stress in many genera including S. mutans (Lemos et al., 2007; Wilkins et al., 2002) and L. lactis (Hartke et al., 1997). Exposure of L. monocytogenes to low pH environments results in a similar increase in expression of these genes, with a resultant increase in protein detected (Gahan et al., 2001; Phan-Thanh et al., 2000). Serine proteases act in a similar manner to chaperonin proteins, by degradation of aberrant proteins which are improperly formed as a consequence of exposure to environmental stress. A gene encoding a serine protease, designated htrA has been identified and characterized in Listeria. The encoded protein has been shown to be involved in the bacterial response to acid exposure (Stack et al., 2005) as well as stress conditions such as heat, ethanol, and osmotic shock (Wonderling et al., 2004). Stack et al. (2005) observed that a mutant lacking this gene exhibited reduced growth rates and final optical densities relative to the parent in acidic conditions, and that under conditions of acid stress, transcription of HtrA in L. monocytogenes is upregulated. Furthermore, in L. monocytogenes htrA is regulated by the two component sensor-regulator LisRK (Sleator and Hill, 2005; Stack et al., 2005).
E. Cell membrane changes In a number of bacterial genera, it has been shown that pH adaptation results in modulation of fatty acid profiles (Fozo and Quivey, 2004a,b; Kim et al., 2005). Similarly, L. monocytogenes cells exposed to environmental stresses such as temperature (Annous et al., 1997), osmotic (Chihib et al., 2003), anaerobic stresses ( Jydegaard-Axelsen et al., 2004), and low pH stress (Giotis et al., 2007) undergo alterations in membrane fatty acid profiles. Giotis et al. (2007) examined the overall content and proportions
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of branched-chain fatty acid (BCFA), straight chain fatty acid (SCFA), and unsaturated fatty acids in cultures of L. monocytogenes 10403S which were exposed to mild pH stress. This study revealed that the BCFA content as well as the relative proportions of anteiso- and iso- fatty acids in the listerial cell membrane are modified upon cellular exposure to pH stress. It appears that the membrane alterations differ from those documented in other genera, where exposure to moderately acidic conditions results in increased levels of monounsaturated long-chain fatty acids (FAs) in the membrane; in Listeria, higher proportions of SCFAs are incorporated into the membrane. van Schaik et al. (1999) observed that in acid-adapted cells, production of the SCFAs C14:0 and C16:0 was increased, with a concomitant decrease in C18:0 detected in the membrane. The authors suggested that the cross-protective effects of acid adaptation could potentially be attributed to this phenotype.
F. Sigma B The ability of Listeria to persist and thrive when subjected to rapidly changing environmental conditions suggests that this bacterium is capable of appropriate responses to external stress (Ferreira et al., 2001). The association of alternative sigma factors with the core RNA polymerase provides a mechanism by which bacterial cells can alter global gene expression by redirection of transcription in response to extracellular signals (Wiedmann et al., 1998). Alternative sigma factors target precise recognition sequences and can thereby control the expression of entire regulons dedicated to specific responses (van Schaik and Abee, 2005). The alternative sigma factor sB of Gram-positive bacteria is analogous to the well-characterized RpoS of Gram-negatives, including E. coli. It appears that SigB and RpoS have parallel roles in the general stress responses of Gram-positive and Gram-negative organisms, respectively (Ferreira et al., 2001; Gertz et al., 2000; Volker et al., 1999). sB is encoded by the sigB gene and has been identified and characterized in detail in a number of Gram-positive bacteria, including L. monocytogenes, B. subtilis, and S. aureus. Recent microarray analysis of the sB regulon in L. monocytogenes revealed 105 sB-positively regulated genes and 111 genes which appeared to be under negative control of sB at various stages of the growth cycle (Hain et al., 2008). The sB regulon therefore represents 7.6% of genes in the L. monocytogenes genome. Of the genes positively regulated by sB, 75 had homologs in B. subtilis, but only 33 had been previously described as sB-regulated in B. subtilis. The data indicate a divergence of the sB regulons between these two bacterial genera, possibly reflecting adaptation to different niches (Hain et al., 2008). A previous partial array study of the sB regulon of L. monocytogenes identified 55 genes within the sB regulon and proved that these were upregulated in a sB-dependent
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manner following osmotic upshift (Kazmierczak et al., 2003). Collectively these studies have demonstrated that a high proportion of L. monocytogenes genes are under the influence of sB, including genes involved in pH homeostasis and gastrointestinal persistence. The response of sB to environmental stresses is transcriptionally mediated (Becker et al., 1998) and appears to be extremely rapid; increased expression of sB-dependent genes was detected within 5 min of exposure to acid and osmotic stresses in L. monocytogenes (Sue et al., 2004). In L. monocytogenes, mutants lacking a functional sigB gene have been characterized in great detail and exhibit decreased resistance to numerous adverse conditions, including starvation, heat, salt, bile, oxidative stresses, as well as low pH (Begley et al., 2005; Ferreira et al., 2001; Wiedmann et al., 1998). It appears that sB contributes to acid resistance through at least two mechanisms: firstly, a general acid tolerance to which sB-regulated systems contribute throughout all growth phases, as well as a pH-inducible ATR mechanism that is at least partially sB-dependent in exponential phase cells (Ferreira et al., 2003; Volker et al., 1999). Becker et al. (1998) discerned from primer extension analyses that SigB activity in log phase L. monocytogenes can be induced from undetectable levels to a level similar to that observed for stationary phase cells following exposure of cells to mildly acidified media (pH 5.3). Given the essential role of GadD2 (formerly GadB) in pH homeostasis and the fact that this locus is sB-regulated, we consider it likely that sB-mediated induction of GadD2 at low pH is a major contributor to acid adpation and the ATR in L. monocytogenes (Cotter et al., 2001a; Kazmierczak et al., 2003). In Listeria, the function of sB appears to be both species and strain dependent. While sB contributes to both stationary and log phase acid resistance in L. monocytogenes, only log phase acid resistance is sB-dependent in L. innocua (Raengpradub et al., 2008). Furthermore, compelling evidence indicates that the sigB gene plays a variable role in stress response in the different genetic lineages of L. monocytogenes (Moorhead and Dykes, 2003). It was shown that a serotype 1/2a strain is more reliant upon an intact sB regulon than a serotype 4c strain across a range of environmental stresses, including low pH (Moorhead and Dykes, 2003). Such variations in environmental stress resistance across different strains may contribute to disparate survival in foods and therefore indirectly to discrepancies in pathogenicity between different strains (Wiedmann et al., 1998). It has been shown that the sB regulon includes genes encoding the classical virulence factors InlA and InlB (Bischoff et al., 2004; Gertz et al., 2000), and sB is required for rapid expression of L. monocytogenes genes which are important for survival of gastrointestinal stresses, including bile salts, elevated osmolarity, and reduced pH (Begley et al., 2005; Hain
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et al., 2008; Sleator and Hill, 2005; Sue et al., 2004). Indeed, loss of sB has been found to result in decreased virulence of L. monocytogenes following oral infection in the murine and guinea pig models (Garner et al., 2006; Nadon et al., 2002). However, mutational analysis revealed that sB is not required for intracellular spread or for intravenous infection in guinea pigs (Garner et al., 2006). Given the critical role of this alternative sigma factor during the gastrointestinal stage of listeriosis (Garner et al., 2006), and the fact that the sB regulon is induced by low pH conditions similar to those encountered during gastrointestinal passage (Sue et al., 2004), it is likely that the relationship between sB and the acid resistance of the bacterium is critical for optimal pathogenesis of Listeria. Furthermore, this alternative sigma factor has the potential to promote bacterial survival both outside and inside a host, thus contributing to survival at all stages of the infectious cycle (Chaturongakul and Boor, 2004; Gahan and Hill, 2005).
G. LisRK two-component regulatory system Two-component signal transduction systems (2CSs) are frequently utilized by bacteria as a means by which they sense and respond to fluctuations in their environments. These molecular systems consist of a membrane-associated histidine kinase sensor, which transduces information about the extracellular environment, operating in combination with a cytoplasmic response regulator, which can modify gene transcription, thereby ensuring an adequate response is mounted to external challenges (Parkinson, 1993; Parkinson and Kofoid, 1992). 2CSs have been characterized in various genera and have been frequently associated with bacterial responses to acid stress. Important examples include PhoPS of E. faecalis (Teng et al., 2002), PhoPQ and EnvZ/OmpR of Salmonella species (Bang et al., 2000; Bearson et al., 1998), and ToxRS of V. cholerae (Merrell et al., 2001). In Listeria, the LisRK 2CS is required to mount an effective response to numerous stresses, including low pH (Cotter et al., 1999, 2002; Sleator and Hill, 2005). Deletion of lisK, encoding the histidine kinase, was found to result in a growth-phase dependent variation in acid tolerance (Cotter et al., 1999), with mutants more resistant to the deleterious effects of lactic acid in stationary phase, but significantly more sensitive in early exponential phase growth (Cotter et al., 1999). Disruption of the response regulator was also found to result in a decreased ability to grow at reduced pH (Kallipolitis and Ingmer, 2001). Mutants lacking a functional LisRK system also exhibit significant sensitivity to cephalosporins (Cotter et al., 2002) and increased ethanol resistance (Cotter et al., 1999), and hence it has been suggested that in the absence of this 2CS, the sensitivity of the cell to low pH may be mediated by changes in the composition of the cell envelope (Hill et al., 2002). We have recently determined that the heat
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shock protein HtrA is induced under low pH conditions in L. monocytogenes and is regulated by LisRK (Sleator and Hill, 2005; Stack et al., 2005). Further analysis is necessary to determine the components of the LisRK regulon.
VII. CONCLUSION The ability to respond appropriately and effectively to extracellular signals is a critical feature of pathogenic bacteria. L. monocytogenes is routinely exposed to suboptimal low pH environments throughout the infectious cycle. Consequently, the ability of the bacterium to maintain intracellular pH homeostasis is central to the process of disease causation. Whilst the importance of some acid response systems (such as the GAD system) is well established, there are many challenges ahead in terms of understanding the interplay between molecular mechanisms governing stress adaptation in this pathogen. This work will be aided by the availability of genomic information for a number of Listeria species and strains and the potential to dissect the transcriptomic and proteomic responses to specific stress conditions. Fundamental to this approach will be the understanding of regulatory networks (including the Sigma B regulon) and how these modulate microbial adaption in complex environments and during infection. In addition, it is clear that distinct serotypes and lineages of L. monocytogenes differ in their ability to respond to acid stress. This has the potential to influence the ability of strains to cross the gastric barrier to infection and may therefore influence the infectious dose of specific strains. An understanding of adaptive responses across a variety of L. monocytogenes strains will be an important goal if we are to predict and model the growth of this pathogen in foods and in the host.
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CHAPTER
4 Global Regulators of Transcription in Escherichia coli: Mechanisms of Action and Methods for Study David C. Grainger* and Stephen J. W. Busby†
Contents
I. Introduction A. An overview of the bacterial multi-subunit RNA polymerase B. DNA recognition by RNA polymerase II. Regulation by Transcription Factors A. An overview of transcription regulators B. Global transcription factors III. Regulation of Transcription by Nucleoid-Associated Proteins A. The nucleoid-associated proteins B. Mechanisms of transcription regulation by Fis, H-NS, and IHF IV. A Novel Method for Studying Transcription on a Global Scale A. Overview of chromatin immunoprecipitation B. Application of ChIP-chip to the study of sequence specific transcription factors C. Application of ChIP-chip to the study of nucleoid-associated proteins D. RNA polymerase-omics E. Protocols for ChIP-chip experiments with E. coli V. Concluding Remarks References
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* Department of Biological Sciences, University of Warwick, Coventry CV4 7AL, UK {
School of Biosciences, University of Birmingham, Edgbaston, Birmingham B15 2TT, United Kingdom
Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00604-7
#
2008 Elsevier Inc. All rights reserved.
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I. INTRODUCTION A. An overview of the bacterial multi-subunit RNA polymerase In bacteria, RNA polymerase exists in two states. One form, known as the core enzyme, can catalyze RNA synthesis but is unable to bind to promoter targets in DNA. The second form of RNA polymerase, the holoenzyme, is capable of both RNA synthesis and promoter recognition. The bacterial RNA polymerase is a multisubunit enzyme and both forms of RNA polymerase posses the a2, b and b0 , and o subunits. The RNA polymerase holoenzyme contains an additional subunit, s, and this is the subunit that facilitates DNA recognition. Following s-mediated DNA binding, transcription initiation occurs, the s subunit then dissociates from the RNA polymerase–DNA–mRNA complex and the core enzyme completes the process of gene transcription. It is estimated that there are ~5000 copies of RNA polymerase in growing Escherichia coli K-12 cells, which must be distributed between ~3000 transcription units. Thus, the cell must carefully regulate the binding of RNA polymerase across its chromosome. RNA polymerase activity can be modulated by DNA sequence elements, transcription factors, nucleoid-associated proteins, small molecules, and RNA polymerase binding proteins (shown in Fig. 4.1).
B. DNA recognition by RNA polymerase Since the s subunit of RNA polymerase is responsible for DNA recognition, it plays a pivotal role in managing the chromosome-wide distribution of the transcriptional machinery. Seven s factors, s70, s54, s38, s32, s28, s24, and sFecI, have been identified in E. coli (Gross et al., 1992, 1998; Helmann and Chamberlin, 1988; Ishihama, 1997) and each s subunit is required by
i) DNA sequence (e.g. promoters)
ii) Transcription factors (e.g. activators and repressors) iii) Nucleoid-associated proteins (Fis, IHF, H-NS etc)
RNA polymerase
iv) Small molecules (e.g. ppGpp)
FIGURE 4.1
v) RNA polymerase binding proteins (e.g. anti-sigma factors)
Factors effecting RNA polymerase activity in E. coli.
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TD
RNA polymerase in order for a specific set of genes to be transcribed. For instance, DNA sequences upstream of genes expressed during exponential growth are usually recognized by s70, the housekeeping s factor. Other s factors are required for the expression of genes needed for; survival during stationary phase (s38), growth in low levels of nitrogen (s54), the heat shock response (s32), chemotaxis (s28), the refolding of denatured proteins (s24), and iron citrate transport (sFecI). The DNA elements recognized by the s subunit of RNA polymerase are ‘‘promoters’’ of transcription. Promoters recognized by s70 contain two well-characterized elements, the 10 and 35 hexamer core promoter sequences, which are located 10 and 35 base pairs upstream of the transcription start site (Fig. 4.2). Consensus sequences, deduced by comparing a large number of promoter sequences, have been defined for these elements (Gralla, 1996) and the location and sequence of these elements varies for the alternative s factors. The degree of identity between the promoter elements at a promoter and the defined consensus sequences determines the basal activity of the promoter. Interestingly, no E. coli promoter has 10 and 35 elements that perfectly match the consensus sequence. Consequently, promoter activity can be enhanced by additional DNA sequences. For example, AT-rich ‘‘UP’’ elements are found upstream of the 35 hexamer at some promoters (e.g., at the promoters for the seven major ribosomal RNA operons). UP elements are typically around 20 base pairs in length and facilitate binding of aCTD, and hence RNA polymerase, to the promoter. This can increase transcription by 30–70 fold (Rao et al., 1994). A surface of the aCTD, known as the 265 determinant, encompasses residues important for DNA binding by aCTD and is required for maximal activity of promoters containing UP elements. (Gaal et al., 1996; Murakami et al., 1996). The ribosomal RNA promoters are amongst the most active and are estimated to sequester large numbers of RNA polymerase molecules during rapid growth (Grainger et al., 2005). Thus, only a fraction of the 5000 RNA polymerase molecules are available for the transcription of other genes.
aN
b/b⬘ s
aCTD UP
+1
–35
–10
FIGURE 4.2 Promoter DNA recognition by RNA polymerase. RNA polymerase is able to recognize promoter DNA via specific interactions between the s subunit of the enzyme and the core (10 and 35) promoter elements. Ancillary promoter elements, such as the UP element that interacts with aCTD, can enhance the affinity of a promoter for RNA polymerase.
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II. REGULATION BY TRANSCRIPTION FACTORS A. An overview of transcription regulators Some promoters are active in the absence of additional factors and when the genes under their control are not required, they are silenced by transcription repressors. However, most promoters lack a good match to the consensus elements for RNA polymerase binding and require ancillary proteins, known as transcription activators, to function. These transcription activators are sequence specific DNA binding proteins that increase the frequency of transcription initiation. Transcriptional activators and repressors share many properties and often exert their effect in response to specific environmental signals. A small number of transcription factors, termed ‘‘global’’ regulators, influence the expression of a large number of transcription units. Conversely, a large number of ‘‘specific’’ transcription factors each affect the expression of a small number of transcription units (Martı´nez-Antonio and Collado-Vides, 2003). The expression of some transcription units, for example the E. coli melAB operon, is regulated by a combination of both global and specific transcription factors (Wade et al., 2001). This allows bacteria to regulate the expression of a small number of genes in response to several environmental stimuli.
B. Global transcription factors The two best characterized global transcriptional regulators in E. coli are CRP (cAMP receptor protein) and FNR ( fumarate and nitrate reductase; reviewed in Browning et al., 2002; Savery et al., 1996). The activity of CRP is regulated by the second messenger cAMP, which is present at high levels in the cell during periods of starvation. Thus, CRP regulates global patterns of transcription in response to carbon availability. FNR directly senses oxygen levels via an iron–sulphur cluster at the N-terminus of the protein and co-ordinates the transcriptional response to oxygen limitation. Much of our understanding of the molecular details of transcription regulation has emerged from detailed studies of CRP and FNR action at a small number of target promoters. Both CRP and FNR predominantly function as activators of transcription and, like most activators, serve to increase levels of promoter occupancy by RNA polymerase. Activators of this type often function by a simple recruitment mechanism and interact specifically with both the promoter and RNA polymerase (Busby and Ebright, 1994; Dove et al., 1997). Promoters regulated by CRP, FNR, and other activators can be grouped into three classes (Busby and Ebright, 1999).
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1. Class I activator dependent promoters At class I activator dependent promoters, the activator protein binds upstream of the core promoter elements. Accordingly, when bound at this location the activator functions by enhancing the binding of the aCTD of RNA polymerase to the promoter, which improves the binding affinity of RNA polymerase (Fig. 4.3A). An example of a class I activator dependent promoter in E. coli is the lac promoter, which is activated by CRP. The interaction between CRP and aCTD at the lac promoter has been investigated extensively; a determinant located between residues 156 and 164 of CRP, Activating Region 1 (AR1), interacts with a region of aCTD close to residue 287, the 287 determinant (Bell et al., 1990; Eschenlauer and Reznikoff, 1991; Niu et al., 1994; Savery et al., 2002; Zhou et al., 1993).
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FIGURE 4.3 Class I and class II activator dependent promoters. Sequence specific transcription factors can enhance binding of RNA polymerase to a promoter by making specific contacts with the DNA and with RNA polymerase. At class I promoters, the activator protein binds upstream and contacts the aCTD of RNA polymerase (A). At class II promoters, the activator binds immediately adjacent to the 35 promoter element and can potentially contact all subunits of RNA polymerase (B). Class III promoters contain multiple activator binding sites (C).
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Although the precise molecular details of the interaction differ, the FNR protein also has an AR1 that interacts with aCTD at Class I promoters (Lee et al., 2000). Interactions between the promoter proximal aCTD and the s70 subunit of RNA polymerase may further stimulate transcription at some Class I activator dependent promoters (Chen et al., 2003; Ross et al., 2003).
2. Class II activator dependent promoters At class II activator dependant promoters, the activator protein binds sequences proximal to the core promoter elements, centered at position 41.5. Thus, the activator is close to all subunits of RNA polymerase and there are more opportunities to interact with the transcriptional machinery (Fig. 4.3B). An example is the E. coli melR promoter, which has a CRP binding site centered 41.5 base pairs upstream of the transcription start site. Here, CRP utilizes determinants in addition to AR1 (Bell et al., 1990; Rhodius et al., 1997; Williams et al., 1991; Zhou et al., 1994). The key determinant is located on the N-terminal domain of CRP, is known as Activating Region 2 (AR2), and interacts with aNTD (Niu et al., 1996). CRP possesses a third activating region (AR3) that is nonfunctional in the WT protein. Substitution of K52, by a neutral or positively charged residue, resurrects functionality of AR3 (Bell et al., 1990; Williams et al., 1991). When active, AR3 gives rise to a significant increase in transcription at class II, but not class I, CRP dependent promoters (Bell et al., 1990; Williams et al., 1991). AR3 is believed to contact region 4 of the s70 subunit of RNA polymerase, which is a target for many regulators of transcription (Dove et al., 2003; Lonetto et al., 1998). Like CRP, FNR has an AR2 and an AR3 that interact with RNA polymerase at class II promoters although the molecular details of these interactions are less well understood (Li et al., 1998).
3. Class III activator dependent promoters Some activator dependent promoters contain multiple binding sequences for one or more transcription factors, and this allows several environmental signals to be incorporated into the process of transcription activation (Fig. 4.3C). Though class III activator dependent promoters contain multiple activator target sequences, the positioning of these binding sites is similar to that seen at simple promoters: activator target sites can be located close to the 35 hexamer and/or positioned further upstream. Thus, the mechanism of transcription activation at complex and simple promoters is thought to be the same: RNA polymerase is recruited to the promoter by interactions between the activator protein and subunits of the transcriptional machinery. Synthetic promoters that contain two CRP or FNR binding sites, located in a combination of promoter proximal (class II) and promoter distal (class I) positions, have been created artificially. Experiments of this type have shown that CRP and FNR are
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capable of activating transcription synergistically when bound to two distinct sites (Barnard et al., 2003; Law et al., 1999). Though poorly studied, complex promoters are common in E. coli.
III. REGULATION OF TRANSCRIPTION BY NUCLEOID-ASSOCIATED PROTEINS A. The nucleoid-associated proteins In addition to RNA polymerase and transcription factors, the chromosome of an E. coli cell is bound by a battery of proteins involved in DNA repair, replication, protection, and folding. The folded E. coli chromosome is called the nucleoid and proteins involved in folding the chromosome are known as nucleoid-associated proteins (reviewed in Dame, 2005; Jin and Cabrera, 2006; Travers and Muskhelishvili, 2005). Nucleoid proteins bind to the DNA with little or no sequence specificity and often induce dramatic bending of the DNA. However, their precise role in regulating chromosome structure is still undetermined. Interestingly, many of the nucleoid-associated proteins can also act as global transcription factors (reviewed in McLeod and Johnson, 2001). With respect to transcription regulation, three of the best studied nucleoid proteins are Fis (Factor for Inversion Stimulation), H-NS (Histone like Nucleoid Structuring protein) and IHF (Integration Host Factor). Although these proteins bind to the DNA with much less specificity than transcription factors like FNR and CRP, they can recognize discrete targets in promoter DNA.
B. Mechanisms of transcription regulation by Fis, H-NS, and IHF Fis is the best characterized nucleoid-associated protein with respect to transcription regulation. For instance, at the ribosomal RNA promoters, Fis binds at a class I position and makes specific contacts with aCTD to aid recruitment of RNA polymerase to the promoter DNA (Aiyar et al., 2002). Similarly, at the proP P2 promoter, Fis binds close to the core promoter elements and activates transcription as a typical class II regulator and again contacts aCTD (McLeod et al., 2002). However, at many other target promoters, Fis regulates transcription via more complicated mechanisms. For example, at the E. coli dps promoter Fis acts as a repressor of transcription by binding close to the core promoter elements, together with RNA polymerase, and preventing promoter opening (Fig. 4.4A). Interestingly, whilst the dps promoter can be served by RNA polymerase containing s70 or s38, Fis only represses transcription by s70 associated RNA polymerase (Grainger et al., 2008).
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FIGURE 4.4 Complex promoter regulation by nucleoid-associated proteins. Nucleoidassociated proteins often bind to promoters and regulate transcription via complicated mechanisms. For example, the E. coli dps promoter (A) is repressed by Fis binding between the core promoter elements and trapping RNA polymerase. At the ilvGMEDA promoter (B) IHF can activate transcription by bending the DNA, rather than interacting directly with RNA polymerase. At the hdeAB promoter H-NS traps RNA polymerase, and represses transcription, by stabilising a DNA repression loop (C).
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As detailed above, activators of transcription often make specific contacts with the transcriptional machinery. However, such an interaction is not always required for transcription activation and a small number of activators can function by bending the promoter DNA. The E. coli nucleoid-associated protein IHF is an example of such a protein. At the ilvGMEDA operon, IHF binds a DNA target site that is 92 base pairs upstream of the ilvGMEDA transcription start point (Fig. 4.4B). The distortion of the DNA that follows IHF binding increases promoter occupancy and open complex formation by RNA polymerase (Parekh and Hatfield, 1996). Like Fis, IHF can act as both an activator and a repressor of transcription. For example, IHF binds to a site at position 88 within the E. coli nirB promoter and interferes with class II FNR dependent transcription activation. Thus, in this instance, IHF does not repress transcription by directly hindering the activity of RNA polymerase but instead acts as an ‘‘antiactivator’’ of FNR (Browning et al., 2000). Whilst Fis and IHF can act as both activators and repressors of transcription, H-NS is thought to function solely as a transcriptional repressor. In several instances (for example at the hdeA promoter), H-NS stabilizes a loop in the promoter that can trap RNA polymerase and block transcription (Fig. 4.4C) (Shin et al., 2005). At other promoters, such as proV, H-NS may simply block DNA binding by RNA polymerase (Nagarajavel et al., 2007). Many promoters regulated by H-NS contain two H-NS binding elements separated by several hundred base pairs. Interaction between H-NS molecules binding at these loci appears to be a key feature of gene regulation by H-NS.
IV. A NOVEL METHOD FOR STUDYING TRANSCRIPTION ON A GLOBAL SCALE A. Overview of chromatin immunoprecipitation As outlined above, protein–DNA interactions play a crucial role in transcription and its regulation. Prior to the genomic revolution, biochemical and genetic approaches were the tools of choice for studying protein–DNA interactions, with many studies focusing on a small number of target promoters. Recently, there has been a shift in emphasis to the study of transcription on a global scale. Chromatin immunoprecipitation (ChIP) is a powerful method that permits protein–DNA interactions to be measured directly, in vivo, and independently of their consequences (reviewed in Aparicio et al., 2004). In ChIP experiments, cells are fixed with formaldehyde, resulting in proteins being covalently attached to DNA sequences to which they are bound. Following crosslinking, cellular nucleoprotein is extracted and sheared into ~500 base
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pair DNA fragments by sonication. The protein of interest is then immunoprecipitated from the cell debris with an appropriate antibody, along with DNA fragments to which it is cross-linked. Protein–DNA cross-links are then reversed and the isolated DNA fragments are analyzed. Segments of the chromosome that were associated with the protein of interest at the moment formaldehyde was added will be enriched in the immunoprecipitated DNA sample. Several different approaches can be used to analyze the DNA sequences in any sample of immunoprecipitated DNA. For example, if the binding of a protein to a known target is being measured, quantitative PCR can be used to determine the enrichment of the target site. Note that, in ChIP experiments, as well as isolating known targets for a given protein, other targets bound by the factor will also be precipitated. Thus, by defining the composition of the entire immunoprecipitated DNA sample, one can map the binding of a protein across an entire genome. This is most commonly done by labeling the immunoprecipitated DNA and hybridizing it to a suitable DNA microarray, along with a differently labeled control sample (genomic DNA or DNA from a mock immunoprecipitation). This allows sections of the chromosome enriched in the immunoprecipitate to be identified. This approach is often referred to as ChIP-chip and allows measurement of protein–DNA interactions across entire genomes (Fig. 4.5) (Iyer et al., 2001; Ren et al., 2000). Until recently, ChIP-chip had been applied mainly to eukaryotic systems. However, because of their small genome sizes, bacteria are ideally suited to methodologies involving microarrays. Additionally, developments in chromosome engineering allow rapid epitope tagging of proteins (Cho et al., 2006; Court et al., 2002; Uzzau et al., 2001). Therefore, proteins for which no antibody is available can readily be studied using ChIP-chip. Below we discuss how recent ChIP-chip studies of global regulators in E. coli and other bacteria have enhanced our understanding of transcription regulation.
B. Application of ChIP-chip to the study of sequence specific transcription factors A major goal in the study of gene regulation is to untangle the transcription regulatory networks of E. coli and other ‘‘simple’’ organisms. To do this, we must catalogue the binding sites of all transcription factors. Initial studies relied on the transcriptomics approach and have been only moderately successful. Such experiments compare the transcriptome (mRNA content) of wild type cells and cells that do not express the transcription factor of interest. The location of transcription factor binding sites is then inferred by identifying transcripts expressed at different levels when the regulator is deleted. While useful, this type of analysis is often
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1. Formaldehyde cross-link protein-DNA complexes 2. Lyse cells 3. Fragment DNA
4. Immunoprecipitate protein-DNA complexes of interest
5. Purify precipitated DNA
6. Analyse with DNA microarray
FIGURE 4.5 An overview of chromatin immunoprecipitation and DNA microarray analysis (ChIP-chip). The figure shows and overview of a ChIP-chip experiment. Cells are first fixed with formaldehyde and then lysed before their nucleoprotein content is fragmented by sonication. Formaldehyde cross-linked protein-DNA complexes of interest can then be immunoprecipitated and the isolated DNA fragments purified, labeled and hybridized to a DNA microarray.
complicated because of secondary effects on transcription that result from removal of the transcription factor. Problems are particularly acute if a global regulator is deleted, as this often has an adverse effect on
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growth-rate. ChIP does not require mutant cells, eliminating the possibility of indirect effects, and allowing the study of essential proteins. Laub et al. (2002) first demonstrated that ChIP-chip could be used to study DNA binding by bacterial transcription factors in their study of the Caulobacter crescentus cell-cycle regulator CtrA. More recent studies have shown that the ChIP-chip approach can be used to measure chromosomewide DNA binding by other sequence specific transcription factors in other bacteria: Fur in Helicobacter pylori (Danielli et al., 2006), CodY (Molle et al., 2003a), Spo0A (Molle et al., 2003b), and SpoIIID (Eichenberger et al., 2004) in Bacillus subtilis, and MelR (Grainger et al., 2004), FNR (Grainger et al., 2007), CRP (Grainger et al., 2005), NsrR (Efromovich et al., 2008), and LexA (Wade et al., 2005) in E. coli. As well as pinpointing transcription factor binding sites, these ChIP-chip experiments have uncovered unexpected phenomena.
1. The E. coli genome is permissive to DNA binding Studies with LexA have shown that it is able to recognize all matches to the LexA consensus binding site in vivo across the chromosome. This shows that there are no sections of the E. coli chromosome that are ‘‘closed’’ for transcription factor binding. This is in contrast to eukaryotes, where histone proteins sequester large tracts of DNA rendering them unrecognizable to transcription factors (Wade et al., 2005).
2. Transcription factors bind to many nonconsensus sites in vivo ChIP-chip studies have shown that some sequence-specific transcription factors bind at nonconsensus sites in vivo. For instance, many CtrA (C. crescentus), LexA (E. coli) and FNR (E. coli) targets identified by ChIP-chip do not contain a good match to the consensus binding site sequence (Grainger et al., 2007; Laub et al., 2002; Wade et al., 2005), and several of the B. subtilis Spo0A targets identified by ChIP-chip are not bound in an in vitro binding assay (Molle et al., 2003b). A likely explanation for this is that multiple transcription factors may bind co-operatively to adjacent DNA sites, in a manner akin to transcription factors binding to enhancers in mammalian cells. Co-operative interactions between transcription factors could reduce the requirement for consensus sequences, or perhaps alter the sequence preference of individual transcription factors. Alternatively, differences in local DNA topology might influence the sequence preference of transcription factors.
3. Transcription factors bind DNA sites with no known function Unexpectedly, many transcription factor binding sites identified by ChIPchip have no obvious role in transcription regulation. For instance, in E. coli FNR protein binds to five targets adjacent to genes not involved in the transcriptional response to oxygen availability and expression of these
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genes is not altered significantly in cells lacking FNR (Grainger et al., 2007). Similarly, many genes adjacent to LexA targets do not display altered activity following the exposure of cells to UV light, which induces rapid degradation of LexA (Wade et al., 2005). There are numerous possible explanations for these observations. For example, the transcription factor may function only in specific contexts. This is probable since, many transcription factors bind to their DNA targets under both activating and nonactivating conditions. Alternatively, the protein may simply act only to ‘‘tweak’’ levels of promoter activity. Another explanation is that some transcription factor target sites simply have no functional relevance and are by-products of evolution.
C. Application of ChIP-chip to the study of nucleoid-associated proteins ChIP-chip has already been used to study the chromosome-wide DNA binding patterns of several nucleoid-associated proteins; H-NS in Salmonella typhimurium LT2 (Lucchini et al., 2006; Navarre et al., 2006) and Fis, H-NS, and IHF in E. coli (Grainger et al., 2006; Oshima et al., 2006). As for studies with sequence specific transcription factors, this work has not only identified lists of targets but has also highlighted unexpected properties of the nucleoid proteins.
1. Fis, IHF, and H-NS are biased towards noncoding sections of DNA In eukaryotes, chromosome folding histone proteins saturate the DNA and have to be removed in order for genes to be transcribed. Although all of the bacterial nucleoid proteins that have been studied by ChIP-chip bind to both coding and noncoding DNA they are all bias towards noncoding sections of the genome, consistent with their proposed ancillary role in transcription regulation (Grainger et al., 2006).
2. H-NS silences ‘‘Foreign’’ DNA
Studies of global H-NS binding in both S. typhimurium and E. coli have shown that sections of the chromosome that have been laterally acquired are rich in H-NS and silenced by binding (Lucchini et al., 2006; Navarre et al., 2006; Oshima et al., 2006). For example, in S. typhimurium, H-NS coats the pathogenicity island SPI1 and occludes the binding of RNA polymerase to render the DNA transcriptionaly silent. It is thought that H-NS repression if relived by the binding of an activator protein that can displace the bound H-NS. Interestingly, in E. coli, it has been found that many locations where H-NS is bound to the DNA also contain RNA polymerase (Grainger et al., 2006; Oshima et al., 2006) perhaps suggesting that trapping of RNA polymerase (as shown in Fig. 4.3Ci) may be a common mechanism of transcription regulation by H-NS.
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3. Many promoters are bound by several nucleoid-associated proteins The frequency at which the nucleoid proteins are found to bind at promoter sites suggests that most E. coli promoters are likely to be bound by at least one of these factors. Thus it seems that there are few naturally occurring simple promoters; most promoters are likely to be regulated by a combination of sequence specific transcription factors and nucleoid proteins.
D. RNA polymerase-omics For those studying global patterns of transcription it is important to measure binding, and changes in the binding, of the transcriptional machinery, and RNA polymerase. Typically, the location of RNA polymerase is inferred by studying global mRNA levels using DNA microarray analysis. Although useful, there are several drawbacks to this approach. For example, if RNA polymerase is bound to the DNA but not actively transcribing a gene then this will be undetectable by measuring mRNA. Moreover, mRNA stability is not uniform and this can affect the apparent levels of any given transcript. A useful alternative to transcriptomics is to measure chromosome-wide DNA binding by RNA polymerase in ChIP-chip experiments (Graniger et al., 2005).
E. Protocols for ChIP-chip experiments with E. coli In this section, we describe protocols for a typical E. coli ChIP-chip study: RNA polymerase redistribution induced by an environmental stress (sodium salicylate treatment). Note that, with modifications, these protocols could be used to study DNA binding by any DNA associated protein under any environmental condition.
1. Immunoprecipitation of DNA targets associated with RNA polymerase 1. Grow two 25 ml cultures of E. coli to an OD650 of 0.4 in LB medium with aeration at 37 C. 2. Add Sodium Salicylate to one of the cultures, to a final concentration of 5 mM, and let the cultures continue to grow for a further 40 min. Formaldehyde is then added to a final concentration of 1% for 20 min before Glycine is added to a final concentration of 450 mM for a further 5 min. Note that when these reagents are added to cultures care should be taken to ensure that cells are not stressed by temperature shifts (caused by removing cultures from shaking water baths, etc.) and so on. 3. Collect the cells from each culture by centrifugation and wash twice with 10 ml of Tris-buffered saline (TBS), pH 7.5 by centrifugation and resuspension of the cells. After the second wash, resuspend cells in
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0.5 ml of lysis buffer (10 mM Tris–HCl, pH 8.0, 20% sucrose, 50 mM NaCl, 10 mM EDTA, 10 mg/ml lysozyme) and incubate for 30 min at 37 C. Note that lysis buffer without lysozyme should be prepared in advance and stored at room temperature. Aliquots of this buffer can then be supplemented with lysozyme prior to use. After lysozyme treatment, lysis is completed by the addition of 4.5 ml of immunoprecipitation buffer (50 mM HEPES–KOH, pH 7.5,150 mM NaCl, 1 mM EDTA, 1% Triton X-100, 0.1% sodium deoxycholate, 0.1% SDS). PMSF is then added to a final concentration of 1 mM and the sample is chilled on ice in preparation for sonication. Sonication is used to fragment the DNA prior to immunoprecipitation of cross-linked protein-DNA complexes. Ideally, the DNA fragments should be between 500 and 1000 base pairs in length. Remove cell debris from the sample by centrifugation. Wash a suitably sized aliquot of Ultralink protein A/G beads (Pierce) three times with TBS prior to use by centrifugation and resuspension of the beads. Note that the beads are delicate and should be centrifuged at a low speed in a bench top microfuge. After the final wash, resuspend the beads to form a 50% slurry. To immunoprecipitate cross-linked RNA polymerase-DNA complexes, add an 800 ml aliquot of the sonicated chromatin to 20 ml of washed protein A/G beads and then 4 ml of monoclonal anti-RNA polymerase (b-subunit) antibody (Neoclone). Mix at room temperature for 90 min on a rotating wheel. After immunoprecipitation, the protein A/G beads are collected and washed in Spin-X columns (Sigma, Cat. No. CLS 8160). The beads are washed twice with 0.5 ml of immunoprecipitation buffer, once in 0.5 ml of immunoprecipitation buffer containing 500 mM NaCl, once with 0.5 ml wash buffer (10 mM Tris–HCl, pH 8.0, 250 mM LiCl, 1 mM EDTA, 0.5% Nonidet P-40, 0.5% Na deoxycholate), and once with 0.5 ml Tris–EDTA, pH 7.5. To remove cross-linked protein-DNA complexes from the beads, resuspend the beads in 100 ml of elution buffer (50 mM Tris–HCl, pH 7.5, 10 mM EDTA, 1% SDS) and incubate the sample at 65 C for 10 min. After centrifugation the flow through from the spin-X column should be retained and the beads can be discarded. Add 10 ml of 40 mg/ml Pronase (Roche) to the flow through and incubate at 42 C for 2 h and 65 C for 6 h. This step can be done overnight using a PCR machine with the sample being cooled to 4 C until they are collected the following day. Purify the DNA fragments using a Qiagen PCR purification kit according to the manufacturer’s protocol. Elute the DNA from the Qiagen column in 30 ml of water and determine the DNA concentration. A single immunoprecipitation usually yields about 100 ng of DNA. Several equivalent immunoprecipitations may set up to increase the final amount of DNA isolated.
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2. DNA labelling, microarray hybridization, and processing
In our experiments, we have used high-density E. coli MG1655 microarrays produced by Oxford Gene Technology (www.ogt.co.uk). Similar arrays are available from other suppliers and should be suitable for analysis of immunoprecipitated DNA produced by these experiments. The arrays that we used comprise 21,321 60-base-long oligonucleotides, with an average spacing between them of 160 base pairs. The probes are not in genome order on the array, which provides a control against array visualisation artifacts. We labeled DNA immunoprecipitated from the ‘‘þsalicylic acid’’ culture with Cy5 and DNA from the ‘‘Salicylic acid’’ culture with Cy3. We then compared the two samples by simultaneous hybridization to the array. Note that there is no amplification of the precipitated DNA in this protocol, which avoids possible artifacts because of amplification bias. 1. Ensure that DNA samples are in a volume of 20 ml and at a minimum concentration of 5 mg/ml. This may mean that DNA isolated from several equivalent immunoprecipitations has to be combined and concentrated using a vacuum centrifuge. Mix the DNA with 20 ml of 2.5x random primer (Bioprime kit, Invitrogen) and 0.25 ml of sterile water and denature by heating to 94 C for 3 min. 2. After denaturation, add 5 ml of dNTP mix (2 mM dATP, 2 mM dGTP, 2 mM dTTP, 0.5 mM dCTP), 3.75 ml of Cy5- or Cy3-labeled dCTP (1 mM; GE Healthcare), and 1 ml of the Klenow fragment of DNA polymerase (Bioprime kit), mix gently, and incubate at 37 C for 2 h. 3. Add a further 0.5 ml of DNA polymerase to each tube and incubate at 37 C for a further 2 h. 4. Purify DNA fragments from the labeling reaction using Qiagen PCR purification columns according to the manufacturer’s instructions. The labeled DNA should be eluted from the column using 50 ml of Qiagen elution buffer. 5. The labeled DNA samples can now be mixed and hybridized to the array according to the manufacturer’s instructions (freely available at www.ogt.co.uk). Oxford Gene Technology arrays are manufactured on an Agilent platform, and hybridizations are best performed in an Agilent SureHyb apparatus.
3. Visualization and analysis of DNA microarray data After scanning the microarray, a list of Cy5 and Cy3 signal intensities is generated for each probe on the array and plotted against the genomic coordinate of the probe. This generates a genome-wide DNA-binding profile for RNA polymerase. This analysis can be done in a Microsoft Excel spreadsheet, and binding sites are localized approximately by comparison of peak heights with a suitable E. coli database. Alternatively,
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the profile can be scrutinized using a ‘‘genome browser,’’ in which the fluorescence ratios are superimposed on the genetic map of E. coli. Oxford Gene Technology’s ChIP Browser software (www.ogt.co.uk) facilitates this type of analysis. An overview of data generated from this type of experiment is shown in Fig. 4.6A. Note that by generating lists of genes up and down regulated by salicylic acid shock (as would be done with a ‘‘transcriptomics’’ experiment), one can view the binding profile of RNA polymerase across transcription units and investigate the subunit composition of the transcriptional machinery at different parts of the chromosome as well (Fig. 4.6B). Changes in RNA polymerase distribution induced by sodium salicylate
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FIGURE 4.6 Changes in chromosome-wide RNA polymerase binding induced by treatment of E. coli cells with Sodium salicylate. The figure shows data from ChIP-chip experiments investigating the redistribution of RNA polymerase across the E. coli chromosome that occurs when cells are treated with Sodium salicylate. In addition to measuring the global redistribution of the transcriptional machinery and identifying up/ down regulated genes (panel A) the data at specific loci can reveal the local distribution and subunit composition of the transcriptional machinery (panels B and C).
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V. CONCLUDING REMARKS New genomic technologies mean that cataloguing all targets for global regulators of transcription is now an achievable goal. As well as determining the regulatory role of each transcription factor, the data generated from such experiments will be particularly useful systems biologists who are modeling the transcription networks of E. coli and other bacteria. It is important to note that, despite our increasing tendency to study transcription on a global scale, we still do not understand the molecular details of transcription regulation by most factors at most promoters in E. coli. Moreover, in less well studied bacteria, and many higher organisms, there is a complete lack of such information. Thus, future research on the function of transcriptional regulators is likely to be targeted at both their global role is well as the fine molecular details of their action.
REFERENCES Aiyar, S. E., McLeod, S. M., Ross, W., Hirvonen, C. A., Thomas, M. S., Johnson, R. C., and Gourse, R. L. (2002). Architecture of Fis-activated transcription complexes at the Escherichia coli rrnB P1 and rrnE P1 promoters. J. Mol. Biol. 316, 501–516. Aparicio, O. M., Geisberg, J. V., and Struhl, K. (2004). Chromatin immunoprecipitation for determining the association of proteins with specific genomic sequences in vivo. In ‘‘Current Protocols in Molecular Biology’’ (F. A. Ausubel, R. Brent, R. E. Kingston, D. D. Moore, J. G. Seidman, J. A. Smith and K. Struhl, Eds.), pp. 21.3.1–21.3.32. Wiley, New York. Barnard, A. M., Green, J., and Busby, S. J. (2003). Transcription regulation by tandem-bound FNR at Escherichia coli promoters. J. Bacteriol. 185, 5993–6004. Bell, A., Gaston, K., Williams, R., Chapman, K., Kolb, A., Buc, H., Minchin, S., Williams, J., and Busby, S. (1990). Mutations that alter the ability of the Escherichia coli cyclic AMP receptor protein to activate transcription. Nucleic Acids Res. 18, 7243–7250. Browning, D. F., Cole, J. A., and Busby, S. J. (2000). Suppression of FNR-dependent transcription activation at the Escherichia coli nir promoter by Fis, IHF and H-NS: Modulation of transcription initiation by a complex nucleo-protein assembly. Mol. Microbiol. 37, 1258–1269. Browning, D., Lee, D., Green, J., and Busby, S. (2002). Secrets of bacterial transcription initiation taught by the Escherichia coli FNR protein. In ‘‘Signals, Switches, Regulons and Cascades: Control of Bacterial Gene Expression’’ (D. Hodgson and C. Thomas, Eds.), pp. 127–142. Cambridge University Press, Cambridge, UK. Busby, S. J., and Ebright, R. H., (1994). Promoter structure, promoter recognition and transcription activation in prokaryotes. Cell 79, 743-746. Busby, S., and Ebright, R. (1999). Transcription activation by catabolite activator protein (CAP). J. Mol. Biol. 293, 199–213. Chen, H., Tang, H., and Ebright, R. H. (2003). Functional interaction between RNA polymerase alpha subunit C-terminal domain and sigma70 in UP-element-and activator-dependent transcription. Mol. Cell. 11, 1621–1633. Cho, B. K., Knight, E. M., and Palsson, B. O. (2006). PCR based tandem epitope tagging system for Escherichia coli genome engineering. Biotechniques 40, 67–72.
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Court, D. L., Sawitzke, J. A., and Thomason, L. C. (2002). Genetic engineering using homologous recombination. Annu. Rev. Genet. 36, 361–388. Dame, R. T. (2005). The role of nucleoid-associated proteins in the organization and compaction of bacterial chromatin. Mol. Microbiol. 56, 858–870. Danielli, A., Roncarati, D., Delany, I., Chiarini, V., Rappuoli, R., and Scarlato, V. (2006). In vivo dissection of the Helicobacter pylori Fur regulatory circuit by genome-wide location analysis. J. Bacteriol. 188, 4654–4662. Dove, S. L., Joung, J. K., and Hochschild, A. (1997). Activation of prokaryotic transcription through arbitrary protein–protein contacts. Nature 386, 627–630. Dove, S. L., Darst, S. A., and Hochschild, A. (2003). Region 4 of sigma as a target for transcription regulation. Mol. Microbiol. 48, 863–874. Efromovich, S., Grainger, D. C., Bodenmiller, D., and Spiro, S. (2008). Genome-wide identification of binding sites for the nitric oxide-sensitive transcriptional regulator NsrR. Methods Enzymol. 437, 209–231. Eichenberger, P., Fujita, M., Jensen, S. T., Conlon, E. M., Rudner, D. Z., Wang, S. T., Ferguson, C., Haga, K., Sato, T., Liu, J. S., and Losick, R. (2004). The program of gene transcription for a single differentiating cell type during sporulation in Bacillus subtilis. PLoS Biol. 2, e328. Eschenlauer, A., and Reznikoff, W. (1991). Escherichia coli catabolite activator protein mutants deficient in positive control of lac operon transcription. J. Bacteriol. 173, 5024–5029. Gaal, T., Ross, W., Blatter, E., Tang, H., Jia, X., Krishnan, V., Assa-Munt, N., Ebright, R., and Gourse, R. (1996). DNA-binding determinants of the alpha subunit of RNA polymerase: Novel DNA-binding domain architecture. Genes Dev. 10, 16–26. Grainger, D. C., Overton, T. W., Reppas, N., Wade, J. T., Tamai, E., Hobman, J. L., Constantinidou, C., Struhl, K., Church, G., and Busby, S. J. (2004). Genomic studies with Escherichia coli MelR protein: Applications of chromatin immunoprecipitation and microarrays. J. Bacteriol. 186, 6938–6943. Grainger, D. C., Hurd, D., Harrison, M., Holdstock, J., and Busby, S. J. (2005). Studies of the distribution of Escherichia coli cAMP-receptor protein and RNA polymerase along the E. coli chromosome. Proc. Natl. Acad. Sci. 102, 17693–17698. Grainger, D. C., Hurd, D., Goldberg, M. D., and Busby, S. J. (2006). Association of nucleoid proteins with coding and non-coding segments of the Escherichia coli genome. Nucleic Acids Res. 34, 4642–4652. Grainger, D. C., Aiba, H., Hurd, D., Browning, D. F., and Busby, S. J. (2007). Transcription factor distribution in Escherichia coli: Studies with FNR protein. Nucleic Acids Res. 35, 269–278. Grainger, D. C., Goldberg, M. D., Lee, D. J., and Busby, S. J. W. (2008). Selective repression by Fis and H-NS at the Escherichia coli dps promoter. Mol. Microbiol. 68, 1366–1377. Gralla, J. D. (1996). Activation and repression of E. coli promoters. Curr. Opin. Genet. Dev. 6, 526–530. Gross, C. A., Lonetto, M., and Losick, R. (1992). Bacterial sigma factors. In ‘‘Transcriptional Regulation’’ (S. L. McKnight and K. R. Yamamoto, Eds.), pp. 129–176. Cold Spring Harbour Press, New York. Gross, C. A., Chan, C., Dombroski, A., Gruber, T., Sharp, M., Tupy, J., and Young, B. (1998). The functional and regulatory roles of sigma factors in transcription. Cold Spring Harb. Symp. Quant. Biol. 63, 141–155. Helmann, J., and Chamberlin, M. (1988). Structure and function of bacterial sigma factors. Ann. Rev. Biochem. 57, 839–872. Ishihama, A. (1997). Adaptation of gene expression in stationary phase bacteria. Curr. Opin. Gen. Dev. 7, 582–588.
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Iyer, V. R., Horak, C. E., Scafe, C. S., Botstein, D., Snyder, M., and Brown, P. O. (2001). Genomic binding sites of the yeast cell-cycle transcription factors SBF and MBF. Nature 409, 533–538. Jin, D. J., and Cabrera, J. E. (2006). Coupling the distribution of RNA polymerase to global gene regulation and the dynamic structure of the bacterial nucleoid in Escherichia coli. J. Struct. Biol. 156, 284–291. Laub, M. T., Chen, S. L., Shapiro, L., and McAdams, H. H. (2002). Genes directly controlled by CtrA, a master regulator of the Caulobacter cell cycle. Proc. Natl. Acad. Sci. 99, 4632–4637. Law, E., Savery, N., and Busby, S. (1999). Interactions between the Escherichia coli cAMP receptor protein and the C-terminal domain of the a subunit of RNA polymerase at class I promoters. Biochem. J. 337, 415–423. Lee, D. J., Wing, H. J., Savery, N. J., and Busby, S. J. (2000). Analysis of interactions between activating region 1 of Escherichia coli FNR protein and the C-terminal domain of the RNA polymerase alpha subunit: Use of alanine scanning and suppression genetics. Mol. Microbiol. 37, 1032–1040. Li, B., Wing, H., Lee, D., Wu, H. C., and Busby, S. (1998). Transcription activation by Escherichia coli FNR protein: Similarities to, and differences from, the CRP paradigm. Nucleic Acids Res. 26, 2075–2081. Lonetto, M., Rhodius, V., Lamberg, K., Kiley, P., Busby, S., and Gross, C. (1998). Identification of a contact site for different transcription activators in region 4 of the Escherichia coli RNA polymerase s70 subunit. J. Mol. Biol. 284, 1353–1365. Lucchini, S., Rowley, G., Goldberg, M. D., Hurd, D., Harrison, M., and Hinton, J. C. (2006). H-NS mediates the silencing of laterally acquired genes in bacteria. PLoS Pathog. 2, e81. Martı´nez-Antonio, A., and Collado-Vides, J. (2003). Identifying global regulators in transcriptional regulatory networks in bacteria. Curr. Opin. Microbiol. 6, 482–489. McLeod, S. M., and Johnson, R. C. (2001). Control of transcription by nucleoid proteins. Curr. Opin. Microbiol. 4, 152–159. McLeod, S. M., Aiyar, S. E., Gourse, R. L., and Johnson, R. C. (2002). The C-terminal domains of the RNA polymerase alpha subunits: Contact site with Fis and localization during co-activation with CRP at the Escherichia coli proP P2 promoter. J. Mol. Biol. 316, 517–529. Molle, V., Nakaura, Y., Shivers, R. P., Yamaguchi, H., Losick, R., Fujita, Y., and Sonenshein, A. L. (2003a). Additional targets of the Bacillus subtilis global regulator CodY identified by chromatin immunoprecipitation and genome-wide transcript analysis. J. Bacteriol. 185, 1911–1922. Molle, V., Fujita, M., Jensen, S. T., Eichenberger, P., Gonza´lez-Pastor, J. E., Liu, J. S., and Losick, R. (2003b). The Spo0A regulon of Bacillus subtilis. Mol. Microbiol. 50, 1683–1701. Murakami, K., Fujita, N., and Ishihama, A. (1996). Transcription factor recognition surface on the RNA polymerase alpha subunit is involved in contact with the DNA enhancer element. EMBO J. 15, 4358–4367. Nagarajavel, V., Madhusudan, S., Dole, S., Rahmouni, A. R., and Schnetz, K. (2007). Repression by binding of H-NS within the transcription unit. J. Biol. Chem. 282, 23622–23630. Navarre, W. W., Porwollik, S., Wang, Y., McClelland, M., Rosen, H., Libby, S. J., and Fang, F. C. (2006). Selective silencing of foreign DNA with low GC content by the H-NS protein in Salmonella. Science 313, 236–238. Niu, W., Zhou, Y., Dong, Q., Ebright, Y., and Ebright, R. (1994). Characterization of the activating region of Escherichia coli catabolite gene activator protein (CAP). I. Saturation and alanine-scanning mutagenesis. J. Mol. Biol. 243, 595–602. Niu, W., Kim, Y., Tau, G., Heyduk, T., and Ebright, R. (1996). Transcription activation at class II CAP-dependent promoters: Two interactions between CAP and RNA polymerase. Cell 87, 1123–1134. Oshima, T., Ishikawa, S., Kurokawa, K., Aiba, H., and Ogasawara, N. (2006). Escherichia coli histone-like protein H-NS preferentially binds to horizontally acquired DNA in association with RNA polymerase. DNA Res. 13, 141–153.
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Parekh, B., and Hatfield, G. (1996). Transcriptional activation by protein-induced DNA bending: Evidence for a DNA structural transmission model. Proc. Natl. Acad. Sci. USA 93, 1173–1177. Rao, L., Ross, W., Appleman, J., Gaal, T., Leirmo, S., Schlax, P., Record, M., and Gourse, R. (1994). Factor-independent activation of rrnB P1—an ‘‘extended’’ promoter with an upstream element that dramatically increases promoter strength J. Mol. Biol. 235, 1421–1435. Ren, B., Robert, F., Wyrick, J. J., Aparicio, O., Jennings, E. G., Simon, I., Zeitlinger, J., Schreiber, J., Hannett, N., Kanin, E., Volkert, T. L., Wilson, C. J., et al. (2000). Genomewide location and function of DNA binding proteins. Science 290, 2306–2309. Rhodius, V., West, D., Webster, C., Busby, S., and Savery, N. (1997). Transcription activation at Class II CRP-dependent promoters: The role of different activating regions. Nucleic Acids Res. 25, 326–332. Ross, W., Schneider, D. A., Paul, B. J., Mertens, A., and Gourse, R. L. (2003). An intersubunit contact stimulating transcription initiation by E. coli RNA polymerase: Interaction of the alpha C-terminal domain and sigma region 4. Genes Dev. 17, 1293–1307. Savery, N., Rhodius, V., and Busby, S. (1996). Protein–protein interactions during transcription activation: The case of the Escherichia coli cyclic AMP receptor protein. Philos. Trans. R. Soc. Lond. B. Biol. Sci. 351, 543–550. Savery, N. J., Lloyd, G. S., Busby, S. J., Thomas, M. S., Ebright, R. H., and Gourse, R. L. (2002). Determinants of the C-terminal domain of the Escherichia coli RNA polymerase alpha subunit important for transcription at class I cyclic AMP receptor protein-dependent promoters. J. Bacteriol. 184, 2273–2280. Shin, M., Song, M., Rhee, J. H., Hong, Y., Kim, Y. J., Seok, Y. J., Ha, K. S., Jung, S. H., and Choy, H. E. (2005). DNA looping-mediated repression by histone-like protein H-NS: Specific requirement of Es70 as a co-factor for looping. Genes Dev. 19, 2388–2398. Travers, A., and Muskhelishvili, G. (2005). Bacterial chromatin. Curr. Opin. Genet. Dev. 15, 507–514. Uzzau, S., Figueroa-Bossi, N., Rubino, S., and Bossi, L. (2001). Epitope tagging of chromosomal genes in Salmonella. Proc. Natl. Acad. Sci. 98, 15264–15269. Wade, J. T., Belyaeva, T. A., Hyde, E. I., and Busby, S. J. (2001). A simple mechanism for co-dependence on two activators at an Escherichia coli promoter. EMBO J. 20, 7160–7167. Wade, J. T., Reppas, N. B., Church, G. M., and Struhl, K. (2005). Genomic analysis of LexA binding reveals the permissive nature of the Escherichia coli genome and identifies unconventional target sites. Genes Dev. 19, 2619–2630. Williams, R., Bell, A., Sims, G., and Busby, S. (1991). The role of two surface exposed loops in transcription activation by the Escherichia coli CRP and FNR proteins. Nucleic Acids Res. 19, 6705–6712. Zhou, Y., Zhang, X., and Ebright, R. (1993). Identification of the activating region of catabolite gene activator protein (CAP): Isolation and characterization of mutants of CAP specifically defective in transcription activation. Proc. Natl. Acad. Sci. USA 90, 6081–6085. Zhou, Y., Merkel, T., and Ebright, R. (1994). Characterization of the activating region of Escherichia coli catabolite gene activator protein (CAP). II. Role at class I and class II CAP-dependent promoters. J. Mol. Biol. 243, 603–610.
CHAPTER
5 The Role of Sigma B (sB) in the Stress Adaptations of Listeria monocytogenes: Overlaps Between Stress Adaptation and Virulence Conor P. O’Byrne1 and Kimon A. G. Karatzas
Contents
1
I. Listeria monocytogenes : An Adaptable Pathogen II. The Sigma Factors of L. monocytogenes III. Sigma B (sB) A. Complex protein–protein interactions control sB activity B. Elucidation of the sB regulon by proteomics and transcriptomics IV. A Central Role for sB in Adaptation to Stress A. sB and osmoregulation B. sB and acid resistance C. sB is involved in cryotolerance D. sB affects piezotolerance E. Antimicrobial resistance and sB F. The role of sB in resistance to bile V. Does Competition between Sigma Factors Influence Growth Rate in L. monocytogenes? VI. Role of sB in Metabolism
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Department of Microbiology, School of Natural Sciences, National University of Ireland Galway, Galway, Ireland Corresponding author: Department of Microbiology, School of Natural Sciences, National University of Ireland Galway, Galway, Ireland
Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00605-9
#
2008 Elsevier Inc. All rights reserved.
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VII. sB Plays Important Role in Virulence A. PrfA and the intracellular stages of infection B. Early and extracellular stages of infection VIII. Conclusions References
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I. LISTERIA MONOCYTOGENES : AN ADAPTABLE PATHOGEN The genus Listeria consists of a group of nonsporulating, low G þ C, facultatively anaerobic, Gram-positive bacteria that includes six species. Of these only one, L. monocytogenes, is pathogenic for humans. This pathogen can be isolated from a wide variety of different environments including soil, water, decaying vegetation, and animal faeces, as well as a range of foods destined for human consumption. Its almost ubiquitous nature is underpinned by a remarkable ability to adapt to and thrive in comparatively harsh environmental conditions (reviewed in Gandhi and Chikindas, 2007). It is one of the few bacterial pathogens, capable of growth at refrigeration temperatures and is even capable of growth at temperatures as low as 0.4 C (Walker et al., 1990). It can tolerate environments with high salt concentrations, being capable of growth in the presence of 2 M NaCl and capable of surviving for extended periods in the presence of 3 M NaCl (Cole et al., 1990). L. monocytogenes is extremely tolerant to bile salts and can even persist and grow within the murine gall bladder (Hardy et al., 2004). It can grow over a pH range of 4.3–11.0 (Farber, 1989; Vasseur et al., 1999), and it displays a strong adaptive acid tolerance response (ATR) that confers significant protection against acidic challenges as low as pH 2.5 (Davis et al., 1996; O’ Driscoll et al., 1997). Efficient transcriptional responses play a key role in allowing this pathogen to successfully inhabit such a diverse range of niches. Transcriptional reprogramming is achieved through the use of a plethora of signalling pathways and transcriptional regulators, but it is the availability of sigma factors that determines which sets of genes get transcribed at any given time, by virtue of their ability to target RNA polymerase to specific promoter sequences upstream from genes and operons.
II. THE SIGMA FACTORS OF L. MONOCYTOGENES The genome of L. monocytogenes encodes a total of five sigma factors (Glaser et al., 2001) (Table 5.1), although some phylogenetic lineages encode only four (Zhang et al., 2003). The principal sigma subunit of RNA polymerase in L. monocytogenes is RpoD (sA) encoded by the rpoD
TABLE 5.1
The sigma factors of L. monocytogenes
Sigma factor
Gene
Alternative gene name
B. subtilis homologue
Phenotye of L. monocytogenes null mutant
s sB
rpoD sigB
lmo1454 lmo0895
sigA sigB
Metzger et al., 1994 Wiedmann et al., 1998
sC
sigC
sigV
sH
sigH
sigV, lmo0423 lmo0243
n/a Stress sensitive, reduced invasiveness Heat sensitive
sigH
Sensitive to alkaline pH
s54
sigL
rpoN, lmo2461
sigL
Resistant to mesentericin Y105
Phan-Thanh and Mahouin, 1999; Rea et al., 2004 Robichon et al., 1997
A
First described in references:
Zhang et al., 2005
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gene (lmo1454). It is a member of the sigma 43 subgroup of the sigma 70 family of sigma factors and is very closely related to SigA, the major housekeeping sigma factor of Bacillus subtilis (Metzger et al., 1994). Sigma 54 (s54) is encoded by the sigL gene (lmo2461 or rpoN) and it was first identified in a screen for L. monocytogenes mutations that conferred resistance to the bacteriocin mesentericin Y105. The s54 protein shares 38% sequence identity with s54 from B. subtilis (Robichon et al., 1997). A transcriptomic and proteomic study identified 77 genes under the control of s54, many with functions in carbohydrate and amino acid metabolism (Arous et al., 2004). Two reports suggest that s54 might play a role in stress tolerance in L. monocytogenes. Firstly, mutants lacking s54 are defective for the ability to utilise the osmoprotectant carnitine, although this finding is independent of effects on the transcription of the known carnitine uptake genes (Okada et al., 2006). Secondly, mRNA corresponding to the sigL gene is known to be present at increased levels when cells are grown at 10 C (Liu et al., 2002). The sigH gene (lmo0243) encodes sigma H (sH), a sigma factor that may be involved in responding to changes in environmental pH, since mutants lacking it grow poorly at alkaline pH (Rea et al., 2004) and its expression is induced in response to acidic pH (Phan-Thanh and Mahouin, 1999). The sigC gene (lmo0423 or sigV) encodes sigma C (sC), a sigma factor that belongs to the extracytoplasmic function (ECF) family of sigma factors (Zhang et al., 2005). The sigC gene is present only in strains of L. monocytogenes that belong to the phylogenetic lineage II of the species (Zhang et al., 2003). Mutants that lack sigC are found to exhibit a temperature sensitive phenotype (Zhang et al., 2005). Finally, sigma B (sB), encoded by the sigB gene (lmo0895), was first identified based on its homology to sigB from B. subtilis. Early studies demonstrated an involvement in both acid tolerance (Wiedmann et al., 1998) and osmoregulation (Becker et al., 1998). Considerable research attention has focused on this sigma factor and this will be the principal focus of this review.
III. SIGMA B (sB) A. Complex protein–protein interactions control sB activity At present little is known about how the activity or the expression of sB in L. monocytogenes is modulated in response to changing environmental conditions. However, the high degree of conservation between the sigB operons in L. monocytogenes and B. subtilis (Fig. 5.1) suggests that similar regulatory mechanisms will apply (Becker et al., 1998; Wiedmann et al., 1998). In B. subtilis the activity of sB is regulated primarily at the posttranslational level by modulating its interaction with an anti-sigma factor, called RsbW (recently reviewed in Hecker et al., 2007). Free RsbW can
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FIGURE 5.1 The conserved sigB operon in L. monocytogenes and B. subtilis. Genes belonging to the sigB operon are indicated as open arrowheads, with sigB itself shown in dark grey. Genes in light grey lie outside of the sigB operon. Promoters are indicated as angled arrowheads and putative transcriptional terminators are indicated as stemloop structures. The percentages of amino acid sequence identity between homologues are indicated. The schematic is drawn to scale.
interact with sB and this association prevents productive interactions between sB and RNA polymerase core enzyme. An antagonist protein (or anti-anti-sigma factor) called RsbV can bind to RsbW and this interaction liberates sB to participate in the initiation of transcription. The capacity of RsbV to associate with RsbW is determined by the phosphorylation state of RsbV. In the unphosphorylated form it interacts with RsbW, thereby releasing sB for participation in transcription, whereas in the phosphorylated form it dissociates from RsbW, allowing the sB-RsbW interaction to occur. This regulatory mechanism is called ‘‘partner switching’’ since it involves RsbW switching between two binding partners, RsbV and sB (Fig. 5.2). The overall phosphorylation state of RsbV is regulated by the actions of two dedicated phosphatases, called RsbU and RsbP, and the kinase activity of RsbW. In rapidly growing cells that are not experiencing significant stresses RsbV mainly exists in the phosphorylated form, which allows the anti-sigma factor RsbW to prevent the association of sB with RNA polymerase. Under these conditions the kinase activity of RsbW out-competes the phosphatase activities of RsbU and RsbP. However when the cells experience stress the phosphatase activities increase, resulting in a more stable interaction between RsbV and RsbW, thereby releasing sB and triggering the induction of the sB regulon. Thus, it appears that the phosphorylation state of RsbV is the principal determinant of whether the sB regulon is expressed or not (Fig. 5.2). The sB regulon in B. subtilis is induced primarily in response to two classes of stress, broadly classified as environmental stress (e.g., elevated temperature or osmolarity) and energy stress (e.g., carbon starvation and ATP depletion). Environmental stress triggers the activation of sB via the RsbU phosphatase (Yang et al., 1996), whereas the energy stress appears to influence sB via RsbP (Vijay et al., 2000). In L. monocytogenes, there is no
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“Stressosome” RsbR
Environmental stress
RsbX
P
RsbR
RsbS
RsbS
P
RsbT Kinase Energy-related stress in B. subtilis
RsbT RsbQ
RsbP
+ P
RsbV RsbW
RNA Pol
sB
RsbU
RsbV
P
RsbW
sB
Kinase
Transcription of sB regulon
FIGURE 5.2 Model for the regulation of sB activity. This model for the regulation of sB activity is based on extensive research performed with B. subtilis, cited throughout the text, but it has not yet been validated in L. monocytogenes. The model proposes that the availability of sB for transcription is regulated by modulating the phosphorylation state of RsbV. In the dephosphorylated state RsbV binds to RsbW and this interaction prevents RsbW from interacting with sB, thereby allowing sB to participate in transcription. The dephosphorylation of RsbV is catalysed by the protein phosphatase RsbU. The activity of this phosphatase is in-turn regulated by modulating the phosphorylation state of upstream proteins, RsbR and RsbS. The ‘‘stressosome’’ is a large 25S protein complex that includes multiple copies of RsbR, RsbS, RsbT as well as homologues of RsbR. In L. monocytogenes energy-related stresses are thought to be transmitted via RsbT, since no RsbP homologue is encoded in the genome. How the initial stress-related signal is sensed by the ‘‘stressosome’’ remains to be determined.
close homologue of RsbP and the available evidence suggests that both energy-related and environmental stresses are sensed through the RsbU phosphatase (Chaturongakul and Boor, 2004). Interestingly, it appears that cold stress can be sensed directly by sB in B. subtilis, independently of either RsbU or RsbP. Indeed this activation can also occur independently of RsbV (Brigulla et al., 2003). The mechanism of phosphataseindependent activation of sB in B. subtilis has not yet been elucidated, nor is it known if this pathway exists in L. monocytogenes. The initial sensory input that triggers the downstream activation of sB in B. subtilis is still not clear. Upstream from RsbU there is another partner switching module that liberates to RsbT from a complex with RsbR and RsbS. RsbT then interacts with RsbU and this interaction promotes the
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phosphatase activity of RsbU. The RsbRST complex is a large multisubunit complex that also includes a number of paralogues of RsbR (RsbRB, RsbRC, RsbRD, and YtvA; Delumeau et al., 2006). The large 25S complex formed by these proteins has been described as a ‘‘stressosome’’ (Delumeau et al., 2006). It is not yet clear whether the RsbS, RsbT, and RsbR proteins from L. monocytogenes are associated with a stressosomelike complex. However, the genome of L. monocytogenes does encode a number of RsbR paralogues, including Lmo0161, Lmo1642, and Lmo1842, as well as the YtvA paralogue, Lmo0799. Although post-translational regulation of sB activity is likely to be critical for the control of sB in L. monocytogenes, it is clear that regulation can also take place at the transcriptional level. Transcription of sigB, which lies in an 8-gene operon comprising rsbR, rsbS, rsbT, rsbU, rsbV, rsbW, sigB, and rsbX (Fig. 5.1), is initiated upstream from rsbV (Becker et al., 1998; Rauch et al., 2005). Transcription of this operon is primarily dependent on the presence of sB (Becker et al., 1998), suggesting that a stimulation of sB activity will rapidly result in an increase in sigB transcript. A variety of different stresses are each known to induce transcription from the sB promoter upstream from rsbV, including salt, ethanol, organic acid, heat shock, and entry into stationary phase (Becker et al., 1998). Growth at cold temperatures also leads to increased transcription from the sB promoter upstream from rsbV (Becker et al., 2000). Of these stresses, osmotic shock (with 4% NaCl) gives rise to the biggest increase in transcription (Becker et al., 1998).
B. Elucidation of the sB regulon by proteomics and transcriptomics In order to understand the role that sB plays in the overall biology of L. monocytogenes, a number of groups have used proteomic and transcriptomic studies to define the full extent of the sB regulon. It is now clear that sB regulates a large and diverse set of genes (probably approaching 200 genes) that are predicted to function in stress tolerance (see Section IV), carbohydrate metabolism (see Section VI), transport and cell envelope processes, and virulence (see Section VII). A proteomic study, aimed at identifying components of the sB regulon that contribute to acid tolerance, found nine proteins whose expression was acid inducible in a sBdependent manner (Wemekamp-Kamphuis et al., 2004b). Recently, we reported the results of a proteomic study of the sB regulon using both conventional two-dimensional gel electrophoresis (2DGE) and a novel approach, based on tandem mass spectrometry, called Isobaric Tags for Relative and Absolute Quantitation (iTRAQ). In this study, 38 proteins expressed in a sB-dependent manner were identified, 17 of which are under positive control by sB (Abram et al., 2008). Promoter mapping of
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several of sB–dependent genes facilitated the definition of a refined sB promoter consensus sequence for L. monocytogenes. The proposed consensus sequence is GTTTNW-N13/14-GGGWADW, where N is any base, W is A or T, and D is A, T, or G (Abram et al., 2008). The availability of the genome sequence for L. monocytogenes (Glaser et al., 2001) has allowed global transcriptional studies to be undertaken. Using a consensus sequence-based search of the L. monocytogenes genome it is possible to identify genes with putative sB promoter sequences. This approach has been used to generate a limited set gene array, carrying 166 putative sB-dependent genes. This gene array allowed the identification of 55 genes that were differentially expressed in a sigB deletion mutant (Kazmierczak et al., 2003). Genes identified in this study included several with stress-related functions, but also several known virulence genes, including members of the internalin family inlA, inlB, inlC2, inlD, and inlE. This study also highlighted the involvement of sB in regulating the expression of many genes with cell wall and/or transport-related functions. A more recent study using a whole genome microarray found 168 genes to be under positive sB control, with 145 of these preceded by a potential sB promoter sequence (Raengpradub et al., 2008). Many of the genes identified have functions in metabolism or transport, while many have undetermined functions. Interestingly, only 65 genes in the nonpathogenic species Listeria innocua are found to be under positive sB control, a result that points to a possible role of sB in adaptating to the host environment (Raengpradub et al., 2008). It is interesting to note that a significant subset of PrfA-regulated genes have potential sB promoter sequences (Milohanic et al., 2003). PrfA is the principal regulator of virulence gene transcription in L. monocytogenes (Chakraborty et al., 1992; reviewed in Scortti et al., 2007; see Section VII). This finding highlights the overlap that exists between the control of the general stress response and the control of virulence-related functions.
IV. A CENTRAL ROLE FOR sB IN ADAPTATION TO STRESS A. sB and osmoregulation L. monocytogenes is one of only a small number of bacterial pathogens that can tolerate low water activities. It is capable of growth at NaCl concentrations as high as 2 M (12% w/v) and can survive extended periods in the presence of 3 M (18% w/v) NaCl (Cole et al., 1990). Central to its osmotolerance are three transport systems that enable the efficient uptake of osmoprotectants, such as glycine betaine (betaine) and carnitine (Angelidis and Smith, 2003; Fraser et al., 2000; Sleator et al., 2003). Two transporters are responsible for betaine uptake; BetL and Gbu (Ko and
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Smith, 1999; Sleator et al., 1999). BetL is a sodium-dependent secondary transporter that shares significant homology to the well-studied solute transporters OpuD and BetP, from B. subtilis and Corynebacterium glutamicum, respectively. Mutants lacking BetL display a slow growth phenotype in complex growth media with elevated osmolarity (Sleator et al., 1999). Gbu is an ATP-dependent betaine transporter and is comprised of three distinct subunits, GbuA, GbuB, and GbuC. Mutants lacking this uptake system are unable to use betaine efficiently as an osmoprotectant and display a cold-sensitive phenotype (Ko and Smith, 1999), suggesting that betaine accumulation is also an important component of cryotolerance. Carnitine uptake occurs predominantly through the activity of OpuC, another ATP-dependent transporter that belongs to the binding protein-dependent subgroup of the ABC transporter superfamily (Fraser et al., 2000, 2003). The OpuC transporter is encoded by a four-gene operon that consists of the opuCA, opuCB, opuCC, and opuCD genes (Fraser et al., 2000). Mutants lacking OpuC are defective for carnitine uptake (Fraser et al., 2000) but some carnitine transport still occurs suggesting the presence of alternative route for the transport of this compatible solute (Fraser and O’ Byrne, 2002; Sleator et al., 2001). The transcription of the gbu, betL, and opuC operons is known to be inducible in response to osmotic shock (Cetin et al., 2004; Fraser et al., 2003; Sleator et al., 2003). Indeed, all three transport systems are also induced at the transcriptional level in response to low temperature growth (Wemekamp-Kamphuis et al., 2004a), a finding that highlights the overlap between osmoregulation and cryotolerance in L. monocytogenes. Putative sB promoters were identified upstream from opuCA (Fraser et al., 2000; Sleator et al., 1999), but not upstream from gbuA (Ko and Smith, 1999). Subsequently, the transcription of opuCA was confirmed to be dependent on sB (Fraser et al., 2003; Sue et al., 2003) and a sB promoter has been mapped 58 bp upstream from opuCA (Kazmierczak et al., 2003). A second study confirmed the sB-dependence of opuCA transcription but identified a somewhat unusual sequence, 47 bp further upstream, as the sB promoter (Cetin et al., 2004). The role of sB in transcribing betL and gbuA is less clear. The osmotic induction of gbuA transcription in L. monocytogenes 10403S was found to occur even in a strain lacking sB (Fraser et al., 2003). However, in the same strain Cetin et al. (2004) identified two promoters upstream from gbuA and confirmed that one of these (gbuAP2) is dependent on sB. Although betL is preceded by a putative sB promoter sequence (Sleator et al., 1999) it appears that its transcription does not depend on this sigma factor (Cetin et al., 2004; Fraser et al., 2003). Therefore, the finding that betaine accumulation is impaired in a DsigB mutant (Becker et al., 1998) is probably accounted for by reduced Gbu expression rather than an effect on BetL.
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B. sB and acid resistance L. monocytogenes can modulate its acid tolerance in response to growth phase and to changes in environmental pH (Davis et al., 1996; O’Driscoll et al., 1997). Within the cell a number of different systems contribute to acid tolerance including, the glutamate decarboxylase (GAD) system (Cotter et al., 2001b, 2005), a variety of general shock proteins with protein repair and chaperone activities, such as DnaK, GroEL, HtrA, the Clp ATPases (reviewed in Cotter and Hill, 2003), as well as a possible role for the F1F0-ATPase (Cotter et al., 2000). The role of sB in acid tolerance was first demonstrated when a DsigB mutant was found to survive poorly at pH 2.5 compared to the wild type strain (Wiedmann et al., 1998). In addition, sB plays a role in the ATR of L. monocytogenes (Ferreira et al., 2003), a response that is induced during exposure to mildly acidic pHs, conferring high levels of protection against extreme low pH. However, the ATR is not abolished in a strain lacking sB, suggesting that other regulatory mechanisms must be employed. sB does not appear to contribute to the growth phase-dependent acid resistance mechanism(s) that are responsible for increased acid resistance in stationary phase (Ferreira et al., 2003). sB primarily influences acid resistance through the activation of the GAD acid resistance system, which is known to play an important role in survival of L. monocytogenes in low pH environments, such as acidified foods (Cotter et al., 2001b) or gastric fluid (Cotter et al., 2001a). Depending on the strain, L. monocytogenes can possess three decarboxylases (gadD1, gadD2, and gadD3) and two glutamate/g-aminobutyrate (GABA) antiporters (gadT1 and gadT2) which are organized in three operons, gadD1T1, gadT2D2, and gadD3 (Cotter et al., 2005). GadD2/T2 are important for survival in severe acid challenges (pH 2.8) and their expression is induced during stationary phase, while GadD1 plays a role enabling growth in mildly acidic conditions (pH 5.1) and it is induced during exponential phase (Cotter et al., 2005). However, the role of GadD3 is still unknown since mutants lacking this decarboxylase have not been possible to generate (Cotter et al., 2005). In a DsigB mutant, the acid-induced transcription of gadD2, gadT2, and gadD3 is essentially eliminated, highlighting the role for sB in acid adaptation (Wemekamp-Kamphuis et al., 2004b). The gadT1 transcript levels are reduced in a sigB mutant, but transcription still appears to be acid inducible, while gadD1 levels actually increase in a sigB background, perhaps to compensate for the reduced expression of the other GAD systems (Wemekamp-Kamphuis et al., 2004b). Potential sB promoter sequences are found upstream of the gadT2D2 and gadD3 operons (Wemekamp-Kamphuis et al., 2004b), but only the gadD3 sB promoter has been confirmed (Kazmierczak et al., 2003).
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FIGURE 5.3 Overview of the Gad system conferring acid tolerance (E. coli). The antiporters GadT1 or GadT2 exchange a glutamate molecule for a molecule of GABA. The glutamate is converted to GABA through a decarboxylation reaction, catalyzed by either GadD1, GadD2 (the role of a third decarboxylase, GadD3, remains unclear). This reaction consumes a proton, which raises the intracellular pH and thereby contributes to the acid resistance of the cell. The exported GABA is also predicted to become protonated when the extracellular pH is low, thereby helping to alkalanise the environment in the vicinity of the cell. A possible alternative fate for GABA within the cell is shown in grey. The presence of a potential succinate semialdehyde dehydrogenase in the L. monocytogenes genome (lmo0913) suggests that GABA may be metabolized to succinate via succinate semialdehyde (SSA).
The present model accounting for GAD-mediated acid tolerance (Fig. 5.3) is based on the observations in Escherichia coli (Castanie-Cornet et al., 1999; Richard and Foster, 2004). In L. monocytogenes this system is proposed to transport glutamate through glutamate/GABA antiporters (GadT1 and GadT2) into the cell, and subsequently to convert it to GABA by the action of GAD (Cotter et al., 2001a, 2005). This decarboxylation reaction is catalyzed by either GadD1 and GadD2 (or possibly GadD3) and involves the consumption of a proton, which raises the intracellular pH and thereby contributes to the acid resistance of the cell (Cotter et al., 2001a). Subsequently, the glutamate/GABA antiporter removes the GABA from the cell in exchange for another glutamate molecule (Cotter et al., 2001a; Wemekamp-Kamphuis et al., 2004b). Interestingly, Abram et al. (2008) have demonstrated that levels of Lmo0913 are reduced in the DsigB mutant while GadT2 is over expressed. Lmo0913 is homologous to succinate semialdehyde dehydrogenase, an enzyme that participates in the catabolism of the intermediate GABA, which is known to be toxic to B. subtilis (Belitsky and Sonenshein, 2002) and other microorganisms
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(Arst, 1976). It is suggested that GadT2 could prevent GABA accumulation that might result from the lack of Lmo0913 in the DsigB mutant strain (Abram et al., 2008). Similarly, Cotter et al. (2005) have suggested that Lmo0913 could potentially compensate for the absence of an antiporter such as GadT2 by ensuring the removal of GABA. Several other proteins that might play a role in acid adaptation (Pfk, GalE, ClpP, and Lmo1580) have been suggested to be regulated by sB as they were not induced in the DsigB mutant in response to sub-lethal acidification (Wemekamp-Kamphuis et al., 2004b). The promoter regions of the corresponding genes contain potential sB recognition sequences, but these have not yet been confirmed experimentally (WemekampKamphuis et al., 2004b).
C. sB is involved in cryotolerance L. monocytogenes is known to be able to grow at temperatures as low as 0.4 C (Walker et al., 1990). This characteristic is at least partly due to its ability to accumulate cryoprotective compounds like carnitine or betaine (Bayles and Wilkinson, 2000; see Section IV.A). Efficient uptake of the compatible solutes betaine and carnitine at low temperatures is sB-dependent and consequently mutants lacking sB grow poorly at low temperatures (Bayles and Wilkinson, 2000). Carnitine is transported via the OpuC uptake system and the transcription of the genes encoding this transporter is under sB control (Fraser et al., 2003; see Section IV.A). However, sB does not seem to play an active role in betL transcription or in betaine utilization (Fraser et al., 2003). A role for sB in cryotolerance has also been suggested by Wemekamp-Kamphuis et al. (2004b), who showed that a DsigB mutant is sensitive to freeze-thaw cycles. However, the role of sB in cryotolerance remains somewhat uncertain since a recent study shows that the transcription of opuC occurs independently of sB at 4 C and also finds that a sigB deletion mutant grows normally at low temperatures (Chan et al., 2007). Whether these apparently conflicting observations reflect strain variations or methodological differences between laboratories remains unclear at present. The transcription of the cold stress genes ltrC (Zheng and Kathariou, 1995) and fri (Hebraud and Guzzo, 2000; Olsen et al., 2005) is known to be at least partially sB-dependent (Chan et al., 2007), but a role for these genes in cryotolerance hasn’t yet been established.
D. sB affects piezotolerance sB plays an important role in the piezotolerance (tolerance to High Hydrostatic Pressure, HHP) of L. monocytogenes as mutants lacking this sigma factor are sensitive to various pressures (Wemekamp-Kamphuis
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et al., 2004b). A possible explanation for this is the activation of the clpP gene which encodes the proteolytic subunit of the Clp ATP-dependent protease (Nair et al., 2000), and is sB-regulated (Wemekamp-Kamphuis et al., 2004b). Work by Karatzas and Bennik, (2002) and Karatzas et al., (2003) has shown that a multiple stress-tolerant mutant in which ClpP is over expressed, is resistant to HHP. In addition, clpP is induced following HHP treatment suggesting that it contributes to piezotolerance (Bowman et al. 2008). Another possible explanation for the involvement of sB in piezotolerance is through the induction of cold shock proteins (CSPs). Two CSPs, detectable on polyacrylamide gels but whose identity is uncertain, are induced during high pressure treatment (Wemekamp-Kamphuis et al., 2002a). Pre-exposure of L. monocytogenes cells to a low temperature results in increased piezotolerance (more than 100-fold increased survival after treatment at 300 MPa) (Wemekamp-Kamphuis et al., 2002a). The CspL cold shock protein might be responsible for the pressuresensitive phenotype of a DsigB mutant, since the gene encoding this protein (cspL) is preceded by a potential sB promoter sequence (Wemekamp-Kamphuis et al., 2004b). However, further work is required to prove that the transcription of this gene is sB-dependent and to genetically identify the sB-regulated components that contribute to piezotolerance.
E. Antimicrobial resistance and sB The resistance of L. monocytogenes to the bacteriocins nisin and lacticin 3147, and the antibiotics ampicillin and penicillin G and V is also under sB influence (Begley et al., 2005, 2006). These compounds act on the cell envelope, suggesting that sB may play a role in controlling membrane integrity. The PVA protein, which is also involved in resistance to bile (see Section IV.F), confers resistance to penicillin V, but not penicillin G (Begley et al., 2005). The corresponding pva gene is homologous to a penicillin V amidase and probably hydrolyses penicillin V to 6-aminopenicillinic acid. Consensus sB binding sites were found in the promoter regions of htrA (lmo0292) and mdrL (lmo1409), suggesting possible regulation by sB (Begley et al., 2006). htrA encodes a putative serine protease, which is required for tolerance of penicillin G (Stack et al., 2005) and for optimal growth at elevated temperatures or in the presence of sub-lethal concentrations of hydrogen peroxide (Wonderling et al., 2004). Furthermore, mdrL which encodes an antibiotic efflux pump could be responsible for efficient efflux of antibiotics (Mata et al., 2000). However, despite the presence of consensus sB binding sites upstream of these genes, no evidence has shown sB-dependent transcription.
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F. The role of sB in resistance to bile Bile is one of the most important defence systems of the body against intestinal pathogens (Hofmann and Eckmann, 2006). Bile acts as a detergent that can solubilize and emulsify lipids contained in the bacterial membranes (Begley et al., 2005; Hofmann, 1999; Hofmann and Eckmann, 2006). Therefore, a tolerance of bile by intestinal pathogens is essential for their ability to colonize the host (see Section VII.B.2). In L. monocytogenes bile tolerance is dependent upon expression of the bilE operon, comprising the bilEA and bilEB genes, which encodes a bile exclusion system (Sleator et al., 2005). The BilE system has similarities with multidrug efflux pumps of Gram negative bacteria as well as bile efflux pumps from higher organisms. Deletion of bilE results in the accumulation of bile intracellularly, suggesting that BilE probably acts to transport bile out of the cell (Sleator et al., 2005). The transcription of bilE is significantly reduced in a DsigB mutant, a finding that is consistent with the presence of a consensus sB–dependent promoter binding site upstream of the bilE start codon (Fraser et al., 2003; Sleator et al., 2005). Apart from bile removal mechanisms, several bacteria also possess bile modification mechanisms. L. monocytogenes possesses one bile salt hydrolase gene (bsh). The bsh gene is known to be regulated by both PrfA (Dussurget et al., 2002) and sB (Sue et al., 2003), although the latter appears to play a more significant role in its regulation (Begley et al., 2005). Both bsh transcript and bile salt hydrolase activity are detectable in the stationary phase of growth in a DprfA mutant, but they are eliminated completely in a DsigB mutant. Furthermore, a DsigB mutant is exquisitely sensitive to bile salts in vitro (Begley et al., 2005). Another sB-regulated gene, pva, also plays an important role in bile tolerance in L. monocytogenes (Begley et al., 2005). However, PVA does not affect the hydrolysis of bile salt and it still remains to be clarified how it influences bile tolerance (Begley et al., 2005).
V. DOES COMPETITION BETWEEN SIGMA FACTORS INFLUENCE GROWTH RATE IN L. MONOCYTOGENES? One of the somewhat unexpected phenotypes displayed by mutants lacking the sigB gene is that they can grow faster than the wild-type under certain culture conditions. In media with limiting glucose mutants lacking sB grow significantly faster than the parent strain. The same is true for mutants lacking either of the two positively acting regulators of sB, RsbT or RsbV (Chaturongakul and Boor, 2004). In complex medium at 3 C, mutants of L. monocytogenes lacking sigB are also found to grow faster than the parent (Brondsted et al., 2003). We have found that a DsigB mutant grows faster than the wild-type in chemically defined
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media supplemented with NaCl (Abram and O’Byrne, unpublished data). In B. subtilis a similar phenomenon has been described; cells lacking sigB have a selective growth advantage in glucose-limited continuous cultures (Schweder et al., 1999). At present there is no clear explanation for these observations, but it is interesting to speculate that sigma factor competition might play a role. In E. coli mutations arise in the rpoS gene, encoding the stress-inducible sigma factor sS, when cells are grown under nutrient limiting conditions (King et al., 2006; Notley-Mcrobb et al., 2002). This finding has been suggested to occur because of the competition that arises between the sigma factors involved in growth-related functions (s70) and in protection or maintenance functions (sS). In this model, sS provides the bacterium with protection against adverse conditions, but at the expense of diverting resources away from growth-related functions. Thus, in the absence of sS more efficient transcription of housekeeping genes allows the cell to grow at a faster rate (Nystrom, 2004). This model represents a plausible explanation for the unexpectedly fast growth of L. monocytogenes mutants lacking sigB under some conditions, but experimentation will be required to rigorously test this idea.
VI. ROLE OF sB IN METABOLISM Apart from its important roles in stress resistance, sB also plays a significant role in regulating metabolism-related functions (Kazmierczak et al., 2003). In B. subtilis and Staphylococcus aureus, sB affects expression of genes involved in metabolic functions related to carbon metabolism, envelope function and turnover (Pane-Farre et al., 2006; Price et al., 2001). In L. monocytogenes genes with metabolism-related functions are very highly represented in the set of genes found to be differentially regulated in a DsigB mutant using microarrays (Kazmierczak et al., 2003). In a more recent microarray study, approximately 30% of the sB-dependent genes detected (47 out of 168) had metabolism-related functions, the largest single category of genes apart from genes of unknown function (Raengpradub et al., 2008). Similarly, a proteomics approach has shown that out of 38 differentially expressed proteins in a DsigB mutant, 22 have functions related to metabolism (Abram et al., 2008). These proteins appear to be involved in the metabolism of alternative carbon sources like glycerol, tagatose, N-acetyl-D-glucosamine, 6-phospho-b-D glucosyl-1,4-D-glucose, and fructose. This role is exemplified by the inability of a DsigB mutant to utilize glycerol efficiently, which is attributed to the lower levels of three proteins that encode subunits of a dihydroxyacetone kinase (Lmo2695, Lmo2696, and Lmo2697) involved in glycerol metabolism (Abram et al., 2008). In addition, sB is involved in the regulation of genes whose products are likely to catalyse reactions of the pentose phosphate
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and glycolytic pathways (Abram et al., 2008). However, it remains unclear whether sB has a dedicated role in regulating metabolism in the cell or whether it merely optimises metabolism in response to perturbations in environmental conditions.
VII. sB PLAYS IMPORTANT ROLE IN VIRULENCE A. PrfA and the intracellular stages of infection The transcription of the majority of virulence-related genes in L. monocytogenes is regulated by the PrfA protein (positive regulatory factor A), a CRP-like DNA-binding protein that binds to its target sequence—a PrfA box—as a homodimer (recently reviewed in Scortti et al., 2007). Two promoters (prfAP1 and prfAP2) are located directly upstream of the prfA gene (Fig. 5.4). prfAP1 is sA–dependent, while prfAP2, which is responsible for the majority of the prfA transcript levels intra- and extracellularly, actually consists of two overlapping promoters that are under the control of sB and sA (Kazmierczak et al., 2006; Rauch et al., 2005). However, haemolysis, which is important for escape from the phagocytic vacuole and thus important for virulence, was similar to that of the wild-type strain for both DsigB and DprfAP2 mutants. The DprfAP1 mutant showed nearly a threefold reduction in hemolytic activity compared to the wild type accompanied by intracellular growth attenuation (Nadon et al., 2002). In addition, elimination of either prfAP1 or prfAP2 resulted in fully virulent mutants in an animal model and only deletion of both promoters resulted in lower virulence (Freitag and Portnoy, 1994). Thus it appears that although sB regulates transcription through prfAP2, it does not contribute to PrfA expression in L. monocytogenes intracellularly (Kazmierczak et al., 2006). This dual regulation of prfA transcription by both sB and sA ensures efficient transcription under a wide variety of
FIGURE 5.4 sA and sB-dependent promoters upstream from the prfA gene. A schematic illustration of the region encompassing the four known promoters driving prfA transcription is shown. The thermosensor element (Johansson et al., 2002) is indicated in black; the promoter elements are indicated as grey boxes; the transcription start sites are indicated by angled arrowheads; the PrfA box and Shine-Dalgarno (SD) elements are labeled; and the plcA gene, which encodes phophatidylinositol-specific phopholipase C, is indicated as a grey arrow. The illustration is not to scale.
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conditions even in the absence of one of the two regulators. In addition, PrfA directly or indirectly activates several genes in association with sB (Milohanic et al., 2003). Sequences similar to the sB consensus promoter sequence are contained upstream from 22 genes whose transcription is PrfA-dependent (Milohanic et al., 2003). Several of these genes (lmo2391, lmo2748, lmo0913, and opuCA) are known to be regulated by sB and this dual regulation may reflect an effort by the bacterium to balance between the expression of virulence and stress-related functions, depending on the prevailing environmental conditions.
B. Early and extracellular stages of infection 1. Survival in the stomach
Although sB does not seem to play a major role intracellularly (see Section VII.A), it is important for the early stages of infection within the host (Fig. 5.5). This is exemplified by the normal virulence of a DsigB mutant injected intravenously into guinea pigs, while the same mutant is significantly attenuated compared to the wild-type when introduced intragastrically to guinea pigs (Garner et al., 2006). Once the contaminated food is ingested, the cells of L. monocytogenes are found in the stomach, which is the first important host defense barrier against foodborne bacterial pathogens (Audia et al., 2001). In the stomach, several mechanisms conferring acid resistance are activated including those regulated by sB (e.g., Gad system). A DsigB mutant is sensitive to synthetic gastric fluid, highlighting the importance of this regulator in surviving the acidic conditions of the stomach (Ferreira et al., 2003; see Section IV.B). This is at least partly due to the activation of the Gad system by sB, which is important for survival in gastric fluid (Cotter et al., 2001; see Section IV.B).
2. Survival in the duodenum and the gall bladder Once the bacterium passes the stomach, it is found in the duodenum which is the first part of the small intestine, into which bile is excreted from the gall bladder (Fig. 5.5). At this stage several mechanisms of resistance to bile (bilE, bsh, pva, and btlB), some of which are sB-dependent, act to chance the survival in this part of the intestinal tract (see Section IV.F). From the duodenum the cells of L. monocytogenes can pass to the small intestine or the gall bladder. Due to their tolerance to bile cells can replicate extracellularly in the gall bladder as shown in Balb/c mice (Hardy et al., 2004). It has also been proposed that growth in this organ might have an impact on pathogenesis or spread of the organism contributing to listeriosis (Hardy et al., 2006). Hardy et al. (2006) showed that transit through the murine bile duct into the intestine can occur within 5 min of induction of gall bladder contraction by food and that
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FIGURE 5.5 sB-dependent genes required for survival and colonisation of the host. L. monocytogenes cells are ingested together with contaminated food and after passage through the oesophagus they enter the stomach where the gadD2, gadT2 genes play a role in surviving the acidic conditions (Cotter et al., 2001a). In the duodenum, the combination of high osmotic stress and bile lead to activation of opuCA, bsh (Sue et al., 2004), and bilE (Sleator et al., 2005). In the gall bladder the bsh (Sue et al., 2004), bilE (Sleator et al., 2005), and pva (Begley et al., 2005) genes are important for survival. When the cells are in the small intestine the genes activated are opuCA, bsh (Sue et al., 2004), bilE (Sleator et al., 2005), and finally inlA and inlB (Lecuit et al., 2004) which help internalization in the intestinal epithelial cells initiating the intracellular stages of the infection. PrfA, the activator of virulence gene transcription, appears to be largely dispensable for survival within the gastrointestinal tract (Faith et al., 2005).
movement of bacteria through the intestinal lumen can occur very rapidly in the absence of fecal material. This is the first time that the gall bladder is shown to be a site of growth for any bacterium in an animal model (Hardy et al., 2006).
3. High osmotic pressure in the small intestine as a signal Once out of the stomach and during the passage through the duodenum and the small intestine, the cells are confronted with the increased osmotic pressure encountered in the lumen of the small intestine and
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the duodenum (Chowdhury et al., 1996). L. monocytogenes is able to adapt to these conditions through efficient use of compatible solutes (Chowdhury et al., 1996; see Section IV.A). One such system regulated by sB is OpuC, which is responsible for the transport uptake of the compatible solutes glycine betaine and carnitine (Fraser et al., 2003; Sue et al., 2003). The uptake of these compatible solutes helps the bacterium to counteract the negative effects of the increased osmotic pressure. It has been demonstrated that deletion of opuC in L. monocytogenes results in lower virulence highlighting the role of osmotolerance in pathogenesis (Wemekamp-Kamphuis et al., 2002b). In addition, loss of OpuC results in a significant reduction in the ability of Listeria to colonize the upper small intestine and cause subsequent systemic infection following peroral inoculation (Sleator et al., 2001). However, deletion of other genes important for osmotolerance, like gbu and betL do not seem to affect virulence (Wemekamp-Kamphuis et al., 2002b). Pre-exposure to osmotic stress can protect against bile, whereas pre-exposure to bile fails to protect against osmotic or bile stress (Sleator et al., 2007). Based on this observation, it has been proposed that increased osmolarity, which is firstly encountered in the duodenum after leaving the stomach might act as a key signal for L. monocytogenes, leading to the induction of a bile protective response (Sleator et al., 2007).
4. Invasion of intestinal epithelium
sB affects the invasiveness of L. monocytogenes in human intestinal epithelial cell lines (Kim et al., 2004, 2005). This effect seems to be primarily due to the sB-dependent regulation of internalins, which are cell wall-anchored proteins that play important roles in pathogenesis of L. monocytogenes. Internalin genes under sB control include inlA, inlB (Kim et al., 2004, 2005), inlC2 and inlD (McGann et al., 2007), and inlD (McGann et al., 2007). InlA is important for invasion of nonprofessional phagocytes such as epithelial cells. It binds to human E-cadherin as a receptor and this contributes to the passage through the human intestinal and placental barrier (Lecuit et al., 2004). PrfA also has some influence on the expression of InlA and InlB (McGann et al., 2007). However, deletion of prfA does not affect dramatically the levels of InlA and InlB, unless it is accompanied by a deletion of sigB, or by growth of the cells in BHI supplemented with charcoal (McGann et al., 2007). In contrast, deletion of sigB has a dramatic effect on the levels of InlA and InlB (McGann et al., 2007) and on the cell invasion mediated by these internalins (Kim et al., 2005). These results suggest that PrfA plays a relatively minor role in cell invasion when sB is present and they highlight the important role that sB plays in the ability of L. monocytogenes to invade cells within the host.
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VIII. CONCLUSIONS It is clear that sB is not a dedicated virulence sigma factor, since non pathogenic species of Listeria also use this sigma factor. Indeed, many of the genes under sB control are the same in L. monocytogenes and in the non pathogenic L. innocua (Raengpradub et al., 2008). However, it appears that sB has been co-opted to participate in virulence-related functions in L. monocytogenes. Perhaps, it is not that surprising that sB, whose principal role is in controlling the general response to stress, should play a role in adapting to the often harsh conditions encountered within the host (low pH, elevated osmolarity, bile salts, etc.). More surprising is its role in regulating the transcription of internalin genes and its partial role in regulating the transcription of prfA. It may be that L. monocytogenes has evolved to sense the harsh conditions present within the gastrointerstinal tract and to coordinate the regulation of the protective functions required in this environment with those necessary for the early stages of establishing an infection. Indeed, to some extent the invasion of host cells can be viewed as a stress response, since it involves an escape from the stressful conditions found in the lumen of the ileum to the comparatively safe environment of the host cell cytoplasm. Although sB appears to play a variety of roles within the cell, the data available suggest that its principal role is in coordinating the general stress response in L. monocytogenes. The various stress-sensitive phenotypes associated with the loss of the sigB gene highlight its importance in protecting the cell against environmental stresses, both outside and within the host. In some cases, the molecular basis for this protection is now well understood (e.g., osmoregulation via Gbu and OpuC), while in others we do not yet understand the molecular basis of the protective mechanisms (e.g., resistance to bacteriocins). Many of the genes identified as being under sB control, in several different studies, have no known functions. Some of these genes are likely to encode novel protective mechanisms and therefore characterizing their molecular functions will give new insights into molecular basis for stress tolerance in L. monocytogenes. Ultimately, it is to be hoped that these insights can be exploited to prevent this important pathogen from establishing life-threatening infections in humans.
ACKNOWLEDGMENTS We are grateful to members of the Bacterial Stress Response Group for helpful discussions. The authors’ research is supported by Science Foundation Ireland, the Marie Curie Transfer of Knowledge Programme (FP6) and by the Irish Department of Agriculture, Fisheries and Food.
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6 Protein Secretion and Membrane Insertion Systems in Bacteria and Eukaryotic Organelles Milton H. Saier,1 Chin Hong Ma, Loren Rodgers, Dorjee G. Tamang, and Ming Ren Yen
Contents
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I. Introduction: Transport Protein Classification II. The Diversity of Protein Translocases in Bacteria and Eukaryotic Organelles III. Complex Inner Membrane Secretory Systems in Bacteria A. Type I (ABC–MFP–OMF-type) protein exporters (Fig. 6.1) B. General secretory translocases (Sec systems; Fig. 6.2) C. Type III flagellar and pathogenicity-related systems (Fig. 6.3) D. Type IV conjugation- and virulence-related (IVSP) systems (Fig. 6.4) E. The putative type VI symbiosis/virulence secretory systems (TC #9.A.34) F. Twin arginine translocation (Tat) systems (Fig. 6.5) IV. Omp Translocases of Gram-Negative Bacteria A. The MTB (Fig. 6.6) B. FUP systems C. Autotransporter-1 (AT-1) systems
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Division of Biological Sciences, University of California at San Diego, La Jolla, California 92093-0116 Corresponding author: Division of Biological Sciences, University of California at San Diego, La Jolla, California 92093-0116
Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00606-0
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D. Autotransporter-2 (AT-2) systems E. The Intimin/Invasin or Autotransporter-3 Systems F. Two-partner secretion (TPS) systems G. OMP insertion porins (OmpIP) V. Protein Translocases of Eukaryotic Organelles A. MPT complexes (TIM-TOM; TC #3.A.8; Fig. 6.7) B. The CEPT complex (Tic-Toc; TC #3.A.9; Fig. 6.9) VI. Comparisons and Overview References
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I. INTRODUCTION: TRANSPORT PROTEIN CLASSIFICATION For several years, our laboratory has been concerned with the phylogenetic characterization and classification of transmembrane transport systems (Saier, 1998). Transporters generally consist of channels or carriers (Saier, 1999), and carriers can function by uniport, cation:solute symport, cation: solute antiport, or solute:solute antiport (Saier, 2000a). Additionally, cytoplasmic protein domains and/or subunits can be superimposed upon these integral membrane channel and carrier proteins to allow the direct coupling of chemical energy to transport, as can be provided, for example, by ATP hydrolysis (Saier, 2000b; Saier and Tseng, 1999). The transporter classification (TC) system (Busch and Saier, 2002) involves transport protein categorization (Table 6.1) in five steps as follows: First, permeases are grouped according to transporter type as follows: category 1, channels; category 2, secondary carriers; category 3, primary active transporters; category 4, group translocators; category 5, transmembrane electron flow carriers; category 8, accessory transport proteins; and category 9, transporters or putative transporters of unknown mechanism of action. Second, these major divisions of transporters are subdivided according to protein structural type or energy coupling mechanism. Third, the resultant permease types are divided into recognizable families. Fourth, these families are subdivided into phylogenetic clusters or subfamilies, and last, within each phylogenetic cluster, all functionally characterized transporters that catalyze different transport processes and/or exhibit different substrate specificities are separately tabulated (Busch and Saier, 2002). The TC system is therefore based on both function and phylogeny. This classification system has been adopted by the International Union of Biochemistry and Molecular Biology (IUBMB). The system is described briefly on the IUBMB website and in more detail in the TC database (TCDB, www.tcdb.org; Saier et al., 2006). It includes all systems currently recognized to catalyze protein secretion and membrane insertion.
Protein Secretion and Membrane Insertion Systems
TABLE 6.1
1
2
3
b c d
Channels/pores A. a-Type channels a B. b-Barrel porins a C. Pore-forming toxins (proteins and peptides) D. Non-ribosomally synthesized channels a E. Holins F. Vesicle fusion pore G. Paracellular channels a
Electrochemical potential-driven transporters A. Porters (uniporters, symporters, and antiporters) B. Non-ribosomally synthesized porters b C. Ion-gradient-driven energizers a
a
Primary active transporters A. P–P-bond hydrolysis-driven transporters B. Decarboxylation-driven transporters C. Methyltransfer-driven transporters D. Oxidoreduction-driven transporters E. Light absorption-driven transporters Group translocators A. Phosphotransfer-driven group translocators B. The nicotinamide ribonucleoside uptake transporters C. The acyl-CoA ligase-coupled transporters
5
Transmembrane electron transfer carriers A. Two-electron carriers B. One-electron carriers
9
a
The TC system of transport protein classificationa
4
8
143
c
Accessory factors involved in transport A. Auxiliary transport proteins B. Ribosomally synthesized protein/peptide toxins that target channels and carriers C. Non-ribosomally synthesized toxins that target channels and carriers
Incompletely characterized transport systems A. Recognized transporters of unknown biochemical mechanism d B. Putative uncharacterized transport proteins C. Functionally characterized transporters lacking identified sequences d
Representatives of these types of systems are known to be capable of exporting proteins and other cell surface macromolecules. These systems can energize proteins translocation, but in the inward direction. These proteins can facilitate protein translocation. Systems included in the 9-category translocate proteins by unknown or poorly defined mechanisms.
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II. THE DIVERSITY OF PROTEIN TRANSLOCASES IN BACTERIA AND EUKARYOTIC ORGANELLES Protein export systems are present in all living organisms. Protein export/ membrane insertion systems currently recognized in living organisms fall into TC categories 1A, 1B, 1C, 1E, 2A, 3A, 9A, and 9B of the TC system (Table 6.2; www.tcdb.org; Saier, 2000a,b; Saier et al., 2006). Table 6.2 lists the organismal distributions and the energy sources of most types of protein secretory pathway (SP) systems that are currently well characterized in living organisms. References cited in this review and in TCDB provide descriptions of the protein families as well as mechanistic information. Currently characterized type I (ATP-binding cassette or ABC-type) protein secretory pathway (ISP) systems (Fig. 6.1) are restricted to some bacteria, especially Gram-negative bacteria, as well as archaea, and a few eukaryotes, although members of the ABC superfamily are found in essentially all living organisms (Davidson and Maloney, 2007; Schmitt et al., 2003; Yamane et al., 2004). The Gram-negative bacterial export systems transport their protein substrates across both membranes of the cell envelope. These systems include ABC efflux pumps (TC #3.A.1.109 and 110) complexed with membrane fusion proteins (MFPs; TC# 8.A.1) and outer membrane factors (OMFs; TC# 1.B.17). ABC-type protein exporters in Gram-positive bacteria often depend upon an MFP for activity but lack an OMF (Harley et al., 2000). This suggests that at least some ABC systems depend on an MFP for activity, but the molecular basis for this observation is not known. In agreement with these suggestions, MFPs, but not OMFs, coevolved with the primary transporters (Dinh et al., 1994). By contrast, general SP (GSP or Sec) systems for protein export across the cytoplasmic membrane are found ubiquitously in all living organisms (Fig. 6.2A; Cao and Saier, 2003). Moreover, the principal channel-forming constituents follow the organismal phylogenies (Fig. 6.2B), suggesting vertical transmission from a common ancestor (Cao and Saier, 2003). The twin arginine targeting translocases (Tat), also for export specifically across the cytoplasmic membrane, are by no means ubiquitous, but they are widely distributed. By contrast, main terminal branch (MTB) systems, responsible for transport of many proteins across the outer membranes of Gram-negative bacteria, are exclusively restricted to these organisms (Sandkvist, 2001). In this article, we refer to the Sec or Tat plus MTB systems as type IISP systems, analogously to the type ISP, type IIISP, and type IVSP systems which translocate their protein substrates across both membranes. Well-characterized type III (flagellar [fla]- and pathogenesis [path]related) and type IV (conjugation [conj]- and virulence [vir]-related) systems have been best characterized in Gram-negative bacteria (Baron and Coombes, 2007). However, flagellar export systems, related to but
TABLE 6.2 Protein secretory pathways (PSP) in Gram-negative bacteria and derived eukaryotic organelles Type (Abbreviation) Name
TC #a
Bacteria Archaea
IMPs—Gram-negative bacterial inner membrane channel-forming translocases 1 ABC (ISP) ATP-binding cassette 3.A.1 þ þ translocase 2 Sec (IISP) General secretory 3.A.5 þ þ translocase 3 Fla/Path (IIISP) Flagellum/virulence- 3.A.6 þ – related translocase 4 Conj/Vir (IVSP) Conjugation-related 3.A.7 þ – translocase 2.A.64 þ þ 5 Tat (IISP) Twin arginine targeting translocase 6 Oxa1 (YidC) Cytochrome oxidase 2.A.9 þ þ biogenesis family 7
MscL
8
Holins
Large conductance mechanosensitive channel family Holin functional superfamily
Eukaryotic organelles 9 MPT Mitochondrial protein translocase 10 CEPT Chloroplast envelope protein translocase
Eukarya
# Proteins/ system Energy
þ
3–4
þ
12
–
>10
–
>10
þ (chloroplasts)
2–4
Holland et al. (2005) GTP or Cao and Saier ATPþPMF (2003) ATP Nguyen et al. (2000) ATP Cao and Saier (2001) PMF Yen et al. (2002b)
þ (mitochondria; chloroplasts)
1
None or PMF
References
ATP
1.A.22
þ
–
–
1
None
Yen et al. (2001); Yi and Dalbey (2005) Pivetti et al. (2003)
1.E.1-21
þ
–
–
1
None
Young (2002)
3.A.8
–
–
þ (mitochondria) 20
ATP
Lister et al. (2005)
3.A.9
(þ)
–
þ (chloroplasts)
GTP
Steiner et al. (2005); Robinson et al. (2000)
3
(continued)
TABLE 6.2 (continued)
11
Type (Abbreviation) Name
TC #a
Bacteria Archaea
Eukarya
# Proteins/ system Energy
Bcl-2
1.A.21
–
þ
1?
None
Crompton et al. (2002)
–
14
ATP; PMF
Peabody et al. (2003)
–
1
None
Yen et al. (2002a)
–
1
None
Eukaryotic Bcl-2 family (programmed cell death)
–
Gram-negative bacterial outer membrane channel-forming translocases þb 1 MTB (IISP) Main terminal branch 3.A.15 – of the general secretory translocase 2 FUP Fimbrial usher 1.B.11 þb – protein – 3 AT Autotransporter-1 1.B.12 þb 4 5
AT-2 OMF (ISP)
6 7
TPS Secretin (II (MTB) and III SP) OmpIP Outer membrane protein insertional porin
8
a b
Autotransporter-2 Outer-membrane factor Two partner secreton Secretin
See Saier (2000a) and Saier et al. (2006). Only identified in Gram-negative bacteria.
References
1.B.40 1.B.17
þb þb
– –
– þ(?)
1 1
None None
Loveless and Saier (1997) Kim et al. (2006) Yen et al. (2002a)
1.B.20 1.B.22
þ þb
– –
þ –
1 1
None None
Yen et al. (2002a) Yen et al. (2002a)
1.B.33
þ
–
þ (mitochondria; chloroplasts)
5
None?
Wu et al. (2005)
Protein Secretion and Membrane Insertion Systems
OM
OMP
Peri
MFP
IM
ABC
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NTP
FIGURE 6.1 Schematic depiction of type I (ABC) protein secretion systems. In all schematic figures, the periplasm (Peri) separates the inner membrane (IM) from the outer membrane (OM) of the Gram-negative bacterial cell envelope. Abbreviations: NTP, nucleoside triphosphate; ABC, an ATP-binding cassette transporter; MFP, a membrane fusion protein; OMP, an outer membrane pore-forming factor.
structurally and phylogenetically distinct from the pathogenesis-type systems, are prevalent in both Gram-negative and Gram-positive bacteria (Christie, 2001; Plano et al., 2001). Type IV conjugation systems are also present in Gram-positive bacteria (Dubnau, 1999; Grynberg et al., 2007; see TCDB), although these systems are still relatively poorly characterized. All proteins of these secretory systems, ISP, IISP, IIISP, and IVSP, as referred here, export proteins across both membranes of Gram-negative bacterial envelopes. They are probably energized by ATP, although GTP and the proton motive force (pmf) may contribute to protein export via the Sec, IIISP, and MTB systems (Economou, 2002). An additional type of system, often termed VISP, has been described, but it is not clear if it is actually a distinct type of system. It may merely be a sequence divergent form of type IV (Pukatzki et al., 2006; Zheng and Leung, 2007). Twin arginine targeting (Tat) translocases, which usually translocate fully folded redox enzymes and other protein complexes into the periplasm of Gram-negative bacteria, are energized by the pmf exclusively. In Gram-negative bacteria, when protein substrates of the Sec and Tat systems are exported from the periplasm to the external milieu, they often use the MTB for final secretion across the outer membrane (Johnson et al., 2006). However, other protein-specific systems can also catalyze this process (Yen et al., 2002b).
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A
SPase I: SecY SPase I
SecD
Sec Sec E G
Yaj C
Sec F
YrtC
SecA SecB
FIGURE 6.2 (A) Schematic depiction of the Escherichia coli general secretory (Sec) system. SPase I and II are signal peptidases. SecA and SecB are preprotein export chaperone proteins. SecA is the ATPase that energize translocation across the SecYEG
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Mitochondrial protein translocases (MPTs; TC #3.A.8), possibly derived from primitive protein translocation systems in a-proteobacteria, appear to have evolved to their current level of complexity after the degeneration of endosymbiotic bacteria into mitochondria (Paschen et al., 2005). Their evolution probably followed transfer of much of their genetic material to the nucleus of the host eukaryotic cell, requiring extensive import (Wickner and Schekman, 2005). Although there are only a few prokaryotic homologues of constituents of these mitochondrial import systems (see also TCDB, TC #1. B.33; Lister et al., 2005), several chloroplast envelope protein translocase constituents of the CEPT family (TC #3.A.9; Schleiff et al., 2003a,b) have bacterial homologues, suggesting an origin in the primordial cyanobacterial cell (Ertel et al., 2005; Paschen et al., 2005; Steiner et al., 2005). The cytochrome oxidase biogenesis (Oxal) family is still poorly characterized. Functional data were first available for mitochondria, and subsequently for plant chloroplasts and bacteria (Luirink et al., 2001; Pohlschroder et al., 2005; Yi and Dalbey, 2005). In both eukaryotic organelles as well as Escherichia coli, these proteins seem to function primarily (but not exclusively) to effect integral membrane protein insertion (Luirink et al., 2005). The large conductance mechanosensitive channels (MscL) possibly have the capability to export small proteins such as thioredoxin as well as osmolytes from the cytoplasm of the bacterial cell following osmotic downshift (see Pivetti et al., 2003 for a review). However, osmotic adaptation rather than protein export is clearly their primary function. Small holin proteins, of which there are more than two-dozen recognized families, form oligomeric pores in membranes. They function to export autolytic enzymes that hydrolyze the peptidoglycan layer of the bacterial cell wall. Export is from the cell cytoplasm to an extracytoplasmic locale where these enzymes can promote cell death (Ramanculov and Young, 2001; Wang et al., 2000; Young, 2002; Young and Bla¨si, 1995). The holin/autolysin pair is usually encoded either by phage genes, in which transmembrane pore. SecDF/YajC is a nonessential complex that facilitates insertion of integral inner membrane proteins into the membrane, either in conjunction with SecYEG or independently. YidC facilitates insertion of integral membrane proteins into the membrane with or without the SecY complex. (B) Phylogenetic tree of sequenced homologues of the SecY protein of E. coli and the Sec61a protein of S. cerevisiae. Reproduced from Cao and Saier (2003), with permission, wherein protein and organismal abbreviations can be found. The tree was generated with the CLUSTAL X and TREEVIEW programs (Thompson et al., 1997; Zhai et al., 2002). Note that the tree reveals one eukaryotic and one archaeal cluster (clusters 2 and 1, respectively) plus ‘‘splinter’’ group members from yeast and plants. The other eight phylogenetic clusters are exclusively of bacterial origin, where the proteins cluster according to the phylogenies of their source organisms (16S rRNAs).
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case they promote cell lysis and phage release, or by bacterial chromosomal genes, in which case they mediate programmed cell death (Srividhya and Krishnaswamy, 2007). Cell death inducing systems of animal cells include the Bcl-2 family proteins (TC#1.A.21), which interact with voltage-dependent anion channel proteins (VDAC; TC# 1.B.8) in the outer membranes and the ATP/ADP exchanger of the mitochondrial carrier family (MC; TC #2.A.29) in the inner membranes of mitochondria (Adams and Cory, 1998; Willis et al., 2005, 2007). Finally, bacteria synthesize and secrete numerous toxins such as diphtheria and tetanus toxins which insert into a host animal cell membrane, forming pores that transport cytoplasmic toxic proteins into the cell. All such toxins are included in TC classification 1.C. Descriptions of these systems as well as references to research concerning them can be found at the TCDB database (www.tcdb.org). These proteins will not be the focus of this review. However, TCDB provides a useful tool that can be used together with this review. A number of systems in addition to the MTB cited above are known to function exclusively in export across the lipopolysaccharide (LPS)containing outer membranes of Gram-negative bacteria (Table 6.2). These systems include: (1) the fimbrial usher porins (FUP) that translocate fimbrial subunits across the outer membranes and assemble these subunits into intact fimbriae (Yen et al., 2002a), (2 and 3) two independently evolving families of autotransporters (AT-1 and AT-2) that exhibit C-terminal, oligomeric, pore-forming, b-barrel domains that are thought to translocate their N-terminal virulence-related protein domains to the external surface of the membrane (Cotter et al., 2005; Kim et al., 2006; Roggenkamp et al., 2003; Thanassi et al., 2005), (4) the two partner secretons (TPS) that include members, most of which translocate and sometimes modify toxins and other exported proteins ( Jacob-Dubuisson et al., 2001; Yen et al., 2003a), (5) secretins, oligomeric pore-forming constituents of types II (MTB) and III (Path) systems (Collins and Derrick, 2007; Thanassi, 2002), and (6) OMFs that are pore-forming constituents that function with type I (ABC) protein exporters to allow protein transport across the outer Gram-negative bacterial membrane in a process coupled to ATP hydrolysis catalyzed by the cytoplasmic membrane ABC exporter (Federici et al., 2005). Finally, (7) the outer membrane protein insertion porin (OmpIP) is a multicomponent system that appears to facilitate insertion of periplasmic b-structured OMPs from the periplasm into this membranous structure (Doerrler and Raetz, 2005; Voulhoux et al., 2003). There are thus eight known, independently functioning systems that specifically effect protein export across or insertion into the inner (cytoplasmic) membranes of Gram-negative bacteria and eight that effect export across or insertion into the outer (LPS) membranes (Table 6.2; Saier, 2006, 2007; Yen et al., 2002a). Interestingly, the inner membrane
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protein export systems can function by a threading mechanism (ABC and Sec), by translocating fully or partially folded subunits (IIISP, IVSP, MscL, and possibly holins), or by translocating fully folded and assembled multisubunit protein complexes (Tat). Strictly outer membrane translocases usually (but not always) function by energy-independent diffusiontype mechanisms that may translocate partially or fully folded substrate proteins. The nature of the substrates of and the translocation mechanisms utilized by the outer membrane FUP, AT-1, AT-2, and TPS family channels are still ill defined, but they probably all translocate unfolded proteins; by contrast, the MTB probably transports folded proteins. In the following sections, we will discuss the functions and phylogenies of these different types of protein secretion systems in Gram-negative bacteria. For recent surveys of protein secretory systems encoded within the genomes of select Gram-negative bacteria (see Barabote et al., 2007; Ma et al, 2003; Yen et al., 2008).
III. COMPLEX INNER MEMBRANE SECRETORY SYSTEMS IN BACTERIA A. Type I (ABC–MFP–OMF-type) protein exporters (Fig. 6.1) Type I ABC macromolecular export systems are widespread in nature. Of the 77 currently recognized families of these strictly ATP-dependent systems, two families are specific for large proteins (TC# 3.A.1.109-110), both from Gram-negative bacteria. Members of four other families export peptides or small proteins (TC# 3.A.1.111-113, 3.A.1.123), and exporters of six other families are specific for complex carbohydrates. These ABC exporters generally consist of two integral membrane domains and two cytoplasmic ‘‘energizer’’ domains that hydrolyze ATP. The systems may recognize a C-terminal targeting sequence in the transported substrate protein, but transport seems to be limited by the size and ease of unfolding of the substrate protein. ABC-type protein export systems, several of which can be present in a single bacterial cell (Ma et al., 2003), can associate with two auxiliary proteins, the MFPs and the OMFs that allow transport across both membranes of the Gram-negative bacterial envelope in a single step as noted above (Holland et al., 2005; see Fig. 6.1). ABC transporters usually exhibit substrate specificities that reflect the phylogenies of these systems (Bouige et al., 2002; Dassa et al., 1999; Saurin et al., 1999). In cases that have been studied, the constituents of these systems seem to have rarely, if at all, undergone shuffling during their evolutionary histories (Kuan et al., 1995; Paulsen et al., 1997a; Tam and Saier, 1993). It is presumed that this restriction reflects a need for strict protein:protein interactions for optimal function (Cao and Saier, 2001; Nguyen et al., 2000; Peabody et al., 2003).
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Comparable studies with the two auxiliary constituents, the MFPs and the OMFs, have revealed that while the MFPs have evolved in parallel with their primary permeases (Dinh et al., 1994), the OMFs have not (Paulsen et al., 1997b). The discovery that MFP homologues are present in Gram-positive bacteria (Harley et al., 2000), and the demonstration that at least some of these proteins essential for transport activity (Axelsson and Holck, 1995; Quadri et al., 1997; Venema et al., 1996) are in agreement with their close connections with the permeases. Recently, high-resolution 3-dimensional structures of both uptakeand efflux-type ABC systems and their accessory proteins have been determined (Hollenstein et al., 2007; Hvorup et al., 2007; Oldham et al., 2007; Ward et al., 2007). MsbA of E. coli is one such efflux system specific for drugs and lipids (Ward et al., 2007) while the solved BtuCDF system, specific for vitamin B12, is an example of an uptake system (Hvorup et al., 2007). Their 3-dimensional structures reveal marked differences between systems catalyzing uptake and efflux particularly in the transmembrane domains, although the ATP hydrolyzing constituents are strikingly similar (Davidson and Maloney, 2007). TolC of E. coli is an OMF that functions with several types of transporters. Its structure has also been solved (Eswaran et al., 2004; Higgins and Linton, 2004; Higgins et al., 2004a,b; Koronakis, 2003; Koronakis et al., 2000, 2004; Touze et al., 2004). The TolC protein exhibits a 3-dimensional fold unlike any previously characterized protein. It forms a trimeric, outer membrane b-barrel pore structure (12 b-strands, 4 per subunit) as well as a transperiplasmic, trimeric, a-helical conduit (12 a-helices: 6 continuous, 6 discontinuous; 4 per subunit) which probably connects the inner membrane permease to the outer membrane pore. The OMF by itself provides the transperiplasmic channel. The MFP probably interlinks the inner and outer membrane transport pathways. However, it may serve other functions (Delepelaire, 2004). This last postulate is consistent with the occurrence of MFP homologues in Gram-positive bacteria that lack outer membranes (Harley et al., 2000). Some of these MFP proteins have been shown to be essential for transport function as noted above.
B. General secretory translocases (Sec systems; Fig. 6.2) Type II GSP (Sec) systems in Gram-negative bacteria consist of essential and auxiliary protein subunits (Rusch and Kendall, 2007; Wickner and Schekman, 2005). Every living organism that has been examined has a Sec system, and most have only one (Cao and Saier, 2003). Nevertheless, only some of the constituents are found universally. The essential E. coli translocase constituents include the universal, heterotrimeric, integral, inner membrane protein complex, SecYEG, the prokaryotic-specific cytoplasmic ATPase, SecA, and several additional proteins, all of which follow the
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phylogenies of the host organisms with few exceptions (Cao and Saier, 2003; see Fig. 6.2A and B). SecA may recruit SecYEG prokaryotic-specific complexes (or vice versa) to form reversible active translocation complexes (Benach et al., 2003). The active assembly includes a SecA homodimer and a SecYEG homodimeric or homotetrameric complex (Scheuring et al., 2005; Tziatzios et al., 2004). SecA is apparently not found in eukaryotes. SecY of E. coli is a 10 TMS protein of about 450 amino acyl residues that is believed to form the protein-translocating channel when complexed with the two small integral membrane proteins, SecE and SecG, each maximally of about 140 amino acyl residues in length (Ito, 1992). The SecYEG complex is ubiquitous, being present in every bacterium, archaeon, and eukaryote with a fully sequenced genome (Kinch et al., 2002). Two auxiliary proteins, SecD and SecF, in E. coli are homologous to members of the RND superfamily (TC #2.A.6; Tseng et al., 1999). They are not present in many organisms, including slowly growing bacteria and all eukaryotes. Another protein, YajC of E. coli, forms a complex with SecD– SecF, both independent of and in complexation with SecYEG (Mu¨ller et al., 2001). The SecDF–YajC complex is not essential for secretion, but it stimulates secretion up to 10-fold, particularly at lower temperatures. The mechanistic role of this auxiliary prokaryotic-specific complex is not clearly defined, but it is not required for maintenance of the pmf (Nouwen et al., 2001) as had been proposed earlier. Although Sec-dependent protein export and integral membrane protein insertion are driven by ATP/GTP hydrolysis, the pmf is stimulatory and may function solely in translocating the C-terminal parts of the unfolded substrate proteins. Thus, it is possible that both energy sources are required for efficient translocation with each acting at different steps (Driessen and Nouwen, 2007; Geller, 1991; Rapoport et al., 1996). Point mutations in SecY have been described that abolish the pmf-dependence of the translocation process, but nucleoside triphosphate hydrolysis appears to be essential under all conditions. Insertion of integral inner membrane proteins in bacteria is dependent on a complex resembling the eukaryotic signal recognition particle (SRP) protein–RNA complex which functions as an essential constituent for protein membrane insertion (Mu¨ller et al., 2001). It has also been shown to play a role in the export of some secretory proteins such as DsbA, b-lactamase, and some autotransporters in E. coli (Sijbrandi et al., 2003; Takamatsu et al., 1997). The primary protein constituents of the bacterial complex, Ffh (an SRP54like protein) and FtsY (an SRP receptor [subunit a]-like protein), probably act as GTP-dependent chaperones, feeding substrate proteins into the SecYEG complex (Driessen and Nouwen, 2007; Rapoport, 2007; Scotti et al., 1999). Insertion of most polytopic inner membrane proteins shows a dependency on Ffh and FtsY as well as the SecYEG channel complex, although in some cases, the Oxa1 homologue in E. coli, YidC, may replace
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this complex (Fro¨derberg et al., 2003; van der Laan et al., 2005). How the SecYEG channel may facilitate membrane protein insertion, based on the high-resolution X-ray structure of the SecYEG channel complex, has been discussed (Collinson, 2005; Rapoport et al., 2004; van den Berg et al., 2004).
C. Type III flagellar and pathogenicity-related systems (Fig. 6.3) Type III secretion systems are typically employed by pathogenic Gramnegative bacteria to deliver virulence proteins, termed effectors, directly into the cytosol of host cells (Ghosh, 2004; Hueck, 1998). The battery of effectors delivered varies widely in support of diverse host–pathogen Path (III)
YopN
YscC
YscJ
YscD
YscURT LcrD
YscQ YscN
FIGURE 6.3 Generalized schematic structure of the Type III/Pathogenicity (flagellarlike) protein secretion system of Yersinia species. YscC is the dodecameric outer membrane secretin while YopN may serve as both YscC anchor and Ca2þ sensor for regulations of Yop synthesis. YscN is the energizing ATPase. Other constituents shown comprise the basic structure of the ‘‘injectisome.’’
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relationships, and these generally function to disable host immunological defenses. In contrast to this effector diversity, roughly half of the proteins comprising the syringe-like type III secretion apparatus, or ‘‘injectosome,’’ are conserved between bacterial species. Most of these conserved proteins are similar to those of the basal body of the flagella, which secrete subunits during assembly and are capable of secreting virulence factor (Young et al., 1999). Protein transport by both types of related systems is dependent on the pmf (Galperin et al., 1982; Minamino and Namba, 2008; Paul et al., 2008; Wilharm et al., 2004), and ATP hydrolysis at the inner membrane (Eichelberg et al., 1994; Emerson et al., 1970; Iino, 1969; Tamano et al., 2000; Woestyn et al., 1994). The structural and functional similarities exhibited by the flagellar and pathogenic type III secretion systems have been explored through phylogenetic analyses, and it has been concluded that either type III systems evolved from flagellar systems or that both systems evolved separately from a common ancestor (Gophna et al., 2003; McCann and Guttman, 2008; Nguyen et al., 2000; Saier, 2004). Genes encoding these proteins are sometimes in the chromosome, in which case they are most frequently found within ‘‘pathogenicity islands’’ which are inserted DNA segments derived from foreign organismal sources (Coburn et al., 2007; Hansen-Wester and Hensel, 2001; Yip et al., 2005). However, they may also be plasmid-encoded. As noted above, while the flagellar proteins have been acquired largely by vertical transmission, horizontal transmission of the pathogenicity systems appears to have dominated their distribution (Nguyen et al., 2000; Saier, 2004). These two related types of systems are thus functionally and structurally equivalent, although their constituents generally cluster separately on a phylogenetic tree (Nguyen et al., 2000). The type III secretion apparatus is composed of 20–25 distinct proteins, most of which are required for the translocation of effectors into host cells. As noted above, genes encoding the injectosome components are typically present within one or more virulence plasmids, although some effector genes can be found clustered within pathogenicity islands on the bacterial chromosome (Hansen-Wester and Hensel, 2001). Yersinia spp. harbor wellcharacterized type III secretion systems and export effectors termed Yops. They disable the host defenses by injecting effectors which modulate the inflammatory response and affect cell survival. Effectors include Rho-GTP binding proteins and focal adhesion proteins (Aepfelbacher et al., 2007). Prior to translocation, most effectors are bound to specialized chaperone proteins known as ‘‘Sycs.’’ These proteins are required for the efficient translocation of their cognate effectors and are thus necessary for bacterial virulence. Chaperones are postulated to function by presenting effectors to the secretion apparatus (Birtalan et al., 2002; Lee and Gala´n, 2004; Lee and Schneewind, 2002) and an additional translocation signal is known to reside within the first 15 amino acids of some of the effector
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proteins, the equivalent mRNA codons, or both (Karavolos et al., 2005; Sorg et al., 2005). In spite of much evidence describing the necessity of this region, a receptor for such a signal remains unidentified. While assembly of the bacterial flagellar filament requires a type III export pathway for ordered delivery of structural subunits from the cytosol to the cell surface, transient interactions with chaperones seem to protect subunits and pilot them to dock at the membrane export ATPase complex. An essential flagellar export protein, FliJ, has a novel chaperone escort function in the pathway. It recruits unladen chaperones for the minor filament-class subunits of the filament cap and hookfilament junctional substructures. FliJ does not recognize unchaperoned subunits or chaperone-subunit complexes, and it associates with the membrane ATPase complex, suggesting a postdocking function (Evans et al., 2006). Empty chaperones that are recruited by FliJ in vitro are efficiently captured from FliJ–chaperone complexes by cognate subunits. FliJ with subunit bound to the target chaperone has a much greater affinity for chaperone than does FliJ alone (Evans et al., 2006). Thus, FliJ recruits chaperones and transfers them to subunits driven by competition for a common binding site. This escort mechanism provides a means by which free export chaperones can be cycled after subunit release, establishing a new facet of the secretion process. As FliJ does not escort the chaperone for the major filament subunit, cycling may offer a mechanism for export selectivity and thus promote assembly of the junction and cap substructures required for initiation of flagellin polymerization. As for the flagellar system, one of the constituents of the IIISP system, YscN of Yersinia species, is the ATPase that is believed to couple ATP hydrolysis to protein export. Six integral inner membrane proteins (LcrD and YscD, R, S, T, and U) may form a complex that provides the transport pathway. The YscC protein, an outer membrane secretin, forms dodecameric pores through which the injectisome penetrates the outer membrane (Burghout et al., 2004a,b; Nguyen et al., 2000). IIISP systems can secrete proteins directly into the host cell cytoplasm without exposure to the extracellular milieu (Coombes and Finlay, 2005). This fact implies the existence of a pore complex that spans the host cell cytoplasmic membrane and is contiguous with the bacterial secretion apparatus. This becomes possible by virtue of the ‘‘needle complex’’ that transports proteins through itself (See Fig. 6.3; Cornelis, 2006; Mota, 2006). The Yersinia proteins that are believed to provide this function are YopB and YopD that span the host cell cytoplasmic membrane and form oligomeric pore complexes (Olsson et al., 2004; Ryndak et al., 2005; Viboud and Bliska, 2005). These putative host cell membrane pore proteins comprise the bacterial type III-target cell pore (IIITCP) family (TC #1.C.36). Flagella and injectosomes possess exquisite and similar mechanisms for exclusively secreting hook or needle proteins during assembly, and then
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switching to filament or Yop secretion upon completion of the respective structure. Injectosome length is determind by YscP, which acts as a molecular ruler to regulate polymerization of the needle subunit YscF (Journet et al., 2003). YscP recognizes the completion of elongation and signals the event to the basal body component YscU which is proteolytically activated to halt the secretion of YscF and begin secretion of LcrV, YopB, and YopD upon contact with a host cell (Agrain et al., 2005; Sorg et al., 2007). These ‘‘translocator Yops’’ localize at the distal tip of the needle and form a pore to penetrate the target cell membrane (Broz et al., 2007; Coombes and Finlay, 2005; Francis and Wolf-Watz, 1998; Hakansson et al., 1996; Hoiczyk and Blobel, 2001; Mueller et al., 2005; Olsson et al., 2004; Ryndak et al., 2005). Based on homology to proteins in Salmonella and E. coli, the Yersinia ATPase YscN (Crepin et al., 2005) is thought to unfold effectors at the base of the needle. They subsequently transverse the extracellular space within the conduit formed by YscF (Crepin et al., 2005). Finally, entry to the host cell cytoplasm is likely achieved via the pore formed by YopB and YopD.
D. Type IV conjugation- and virulence-related (IVSP) systems (Fig. 6.4) Protein complexes of the IVSP family consist of multiple subunits that span the two membranes and the peptidoglycan cell wall of the Gram-negative bacterial cell envelope or the single membrane plus wall of the Grampositive bacterial cell envelope (Fig. 6.4). In acid fast bacteria (Mycobacteria, Nocadia, and Corynebacteria), they may penetrate the outer mycolic acid-containing membrane as well. They export proteins and DNA–protein complexes out of the cell and into the cytoplasm of a recipient cell (Christie and Cascales, 2005; Winans et al., 1996). These systems are very promiscuous, being capable of transporting various DNA–protein complexes into cells of other bacteria, yeast, animals, and plants, and also into the external medium (Hamilton et al., 2005; Li et al., 2005). For example, the VirB systems of agrobacterial species are specifically designed to transfer T-DNA into plant cells causing cancerous growth, but they can also transfer the IncQ plasmid RSF1010 into both plant and bacterial cells (Bohne et al., 1998). Further, the various Inc IVSP systems are designed to mediate plasmid transfer from the donor bacterium to a recipient bacterium, but cross-specificity has been demonstrated (Lybarger and Sandkvist, 2004). C-terminal sequences of proteins covalently or noncovalently linked to the DNA may be recognized as a prelude to nucleoprotein transport (Christie and Cascales, 2005). While proteins in addition to the VirB2-B11 proteins may be involved in the transfer process, the VirB proteins appear to be the primary ones involved in export from the cytoplasm across the two membranes of the agrobacterial envelope. Schematic models of type IVSP systems such as that shown in Fig. 6.4 have been presented, each
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Vir (IV)
VirB5
VirB7 VirB9
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FIGURE 6.4 Generalized schematic view of the type IV conjugation/virulence protein secretion system of Agrobacterium species. Two ATPases (VirB4 and VirB11) serve as ATPases. Other proteins comprise the structural elements of the secretion apparatus. Different type IV systems differ strikingly in their protein compositions.
emphasizing different aspects of these highly variable systems (Cao and Saier, 2001; Chen et al., 2005; Christie and Cascales, 2005). The VirB system of A. tumefaciens is related to (1) a natural competence (CAG; ComB) system of Helicobacter pylori which may also be involved in transfer of virulence factors including the CagA antigen into host animal cells by a type IV secretion-related mechanism; (2) the Ptl system, involved in secretion of pertussis toxin from the Bordetella pertussis cell; (3) the TraS/TraB system of the Pseudomonas aeruginosa conjugative plasmid, RP1; (4) the Trb system of plasmid pTiC58 of Agrobacterium, one of three genetically encoded systems for conjugal transfer of this Ti plasmid; (5) the Tra system of plasmid F in E. coli; and (6) the Dot conjugative transfer/virulence system of Legionella pneumophila (Chen et al., 2005; Christie et al., 2005; Ninio and Roy, 2007). There are also more distantly related putative IVSP proteins in Gram-positive bacteria.
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Although members of the type IV secretion family share many characteristics, not all systems contain the same sets of genes. Thus, the virB systems of Ti plasmids and the trb system of RP4 have only six recognized genes in common. The distantly related CAG system of H. pylori contains at least eight known constituents with little sequence similiarity to the Vir system (Karnholz et al., 2006), and the dot system of L. pneumophila contains only two easily recognizable virB homologues. Homologues of only one VirB protein, VirB10 (TrbI) are demonstrably present in all known type IV secretion systems characterized (Cao and Saier, 2001). Structural and functional models for the conjugative transfer of DNA– protein complexes through the A. tumefaciens VirB–VirD4 system have been presented (Chen et al., 2005; see Fig. 6.4). Transport of proteins and DNA–protein complexes has been thought to occur in a single energy-coupled step. However, this hypothesis has been challenged by the observation of periplasmic intermediates of IVSP substrates (Pantoja et al., 2002). It is possible that, as originally proposed, transport across both membranes is normally linked, but that some periplasmic leakage can occur. Alternatively, high affinity capture following periplasmic release could account for these observations.
E. The putative type VI symbiosis/virulence secretory systems (TC #9.A.34) Some Vibrio cholerae strains do not cause cholera and instead cause other human infections by poorly understood mechanisms. One such strain possesses on its small chromosome a 15 cistron operon. The encoded 15 proteins have been reported to catalyze protein secretion by a mechanism that does not require the presence of a hydrophobic N-terminal sequence (Pukatzki et al., 2006). The protein substrates can be secreted into the extracellular medium and possibly into eukaryotic cells. The genes have been named vasA-L (virulence-associated secretion) or the type VI secretion system (T6SS; Pukatzki et al., 2006). At least some of the vas genes are required for cytotoxicity by a contact-dependent mechanism. Many Gram-negative bacteria have sets of homologous genes as well as potential effector-encoding genes. The V. cholerae Vas system may secrete proteins called Hep, VrgG1, VrgG2, and VrgG3. VasK (1181 aas) resembles IcmF (973 aas; AAU26555) of the L. pneumophila Dot system throughout most of its length. Similarly, VasF (257 aas) resembles IcmH (261 aas; AAU26556) of the Dot system throughout most of its length, and like the VasF protein, IcmH shows four peaks of hydrophobicity with the first and last being most hydrophobic. VasF and IcmH also show some sequence similarity with portions of OmpA/MotB proteins, possibly reflecting possession of a peptidoglycan binding domain. While 15 cistrons are present in the vas operon, it is unlikely that they all function directly in transport.
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For example, VasG resembles the E. coli ClpB ATP-dependent, stressinduced, heat shock chaperone protein that uses ATP hydrolysis to unfold denatured proteins in conjunction with DnaJK and GrpE in E. coli. Moreover, VasH resembles a sigma-54 dependent transcriptional activator, and a sigma-54 homologue is encoded downstream of the vas operon. Only VasA, VasF and VasK have been shown to promote virulence. The energycoupling mechanism is unknown (Pukatzki et al., 2006). In Edwardsiella tarda, an E. tarda virulent protein (EVP) gene cluster has recently been implicated in protein secretion (Zheng and Leung, 2007). The entire EVP cluster resembles the T6SS of V. cholerae. All of the 16 evp operon genes were mutagenized; the secretion of EvpP appeared to be dependent on 13 of the proteins including EvpC (a homologue of Hcp) and EvpI but not EvpD and EvpJ. The 16 EVP proteins could be grouped according to their functions and cellular locations. The first group comprises 11 nonsecreted and possibly intracellular apparatus proteins. Among them, EvpO, a putative ATPase which contains a Walker A motif, shows possible interactions with three EVP proteins (EvpA, EvpL, and EvpN). The second group includes three secreted proteins (EvpC, EvpI, and EvpP). Secretion of EvpC and EvpI may be mutually dependent, and these two proteins are apparently required for the secretion of EvpP. An interaction between EvpC and EvpP was demonstrated. However, as noted above, two proteins (EvpD and EvpJ) are not required for the T6SS-dependent secretion (Zheng and Leung, 2007). The resemblance between constituents of the VISP and IVSP systems noted above leads to the possibility that type VI systems are sequence divergent type IV systems. Indeed, the extensive component sequence divergence of the latter systems further substantiates this proposal. Also in Gram-positive bacteria, the putative type IV secretion systems are surprisingly complex and diverse. Further studies will be required to put these observations into a clear, evolutionary framework.
F. Twin arginine translocation (Tat) systems (Fig. 6.5) The TatABCE system of E. coli, has been extensively characterized (Bru¨ser, 2007; Sargent et al., 2006; Yen et al., 2002b). This system forms a large (600 kDa) complex which interacts with fully folded substrate redox proteins that have N-terminal (S/T)RRXFLK ‘‘twin arginine’’ leader motifs (Mu¨ller, 2005). It translocates several redox enzymes to the E. coli periplasm including nitrate reductase (NapA), formate dehydrogenase (FdnGHI), dimethylsulfoxide reductase (DmsABC), and trimethylamine N-oxide reductase (TorA), all of which have this leader motif (Gralnick et al., 2006; Sambasivarao et al., 2000, 2001, 2002; Stanley et al., 2002). Hydrogenases, formate dehydrogenases, and several other proteins, including non-redox proteins and some integral membrane proteins (several dozen altogether in
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Tat System
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RR Tat-exported precursor protein
FIGURE 6.5 Schematic diagram of the E. coli twin arginine targeting translocase (Tat) system. This system uses the proton motive force (pmf) to drive secretion. TatC may serve as the cytoplasmic receptor as well as the intramembrane proton channel. TatA/E monomers assemble to form the channel of variable sizes that can accommodate fully folded and assembled substrate protein complexes. The N-terminal twin arginine signal sequence of the substrate protein is removed (proteolytically cleaved) following secretion through the cytoplasmic membrane.
E. coli), use this pathway (Berks et al., 2005). These proteins associate with their cofactors in the cell cytoplasm before translocation. Tat systems apparently function independently of other types of protein secretory systems present in E. coli (Palmer et al., 2005). Only one TatA/B/E homologue and TatC are absolutely required for function (Bogsch et al., 1998; Hicks et al., 2005; Sargent et al., 1999). TatA, TatB, and TatE are paralogues of each other and exhibit a single TMS each (Mu¨ller and Klo¨sgen, 2005). TatA and TatE exhibit much more similarity in sequence to each other than they do to TatB (Yen et al., 2002b), and they can functionally substitute for each other. TatA (the major, more conserved constituent) and TatB (the minor, less conserved constituent) may together comprise large cylindrical channel-forming complexes of variable diameters that may serve as the channel for protein translocation (see Fig. 6.5; Gohlke et al., 2001; Hicks et al., 2005). TatE is absent in many species such as P. aeruginosa (Yen et al., 2002b). Homologues of representative E. coli Tat proteins are found in a variety of Gram-negative and Gram-positive bacteria, archaea, and thylakoid membranes of plant chloroplasts (van Dijl et al., 2002; Yen et al., 2002b). TatC, with six putative TMSs, may serve as a specificity determining receptor for the complex (Jongbloed et al., 2000). Substrate proteins bind to the receptor complex, inducing formation of the proteintranslocating channel (Berks et al., 2003, 2005; Dabney-Smith et al., 2006;
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Gerard and Cline, 2006). An organism may encode within its genome 1, 2, or 3 TatA homologues, and 1, 2, or 3 TatC homologues, but no organism with a completely sequenced genome examined for these proteins encodes one but not the other (Yen et al., 2002b). Homologues are not demonstrable in yeast, in animals, or in many prokaryotes, particularly those with small genomes and a fermentative lifestyle. Thus, these systems are not ubiquitous as are GSP (Sec) systems (Cao and Saier, 2003), but they are wide spread. Energy coupling for transport involves the pmf both in chloroplasts and in E. coli (Mu¨ller, 2005; Theg et al., 2005). A protein:proton antiport mechanism is inferred (Berks et al., 2003, 2005; Theg et al., 2005). Possibly the TatC receptor provides the Hþ channel function, TatB provides interconnecting interfaces between TatC and the TatA complex, and the large multi subunit TatA complex, of variable sizes and numbers of subunits, depending on the size of the protein substrate complex, comprise the protein translocating channel (see Fig. 6.5). A TatC phylogenetic tree revealed tremendous diversity in the sequences of these proteins (Yen et al., 2002b). All of the low G þ C Gram-positive bacterial homologues proved to cluster together as did the high G þ C Gram-positive bacterial homologues, and most of the Gram-negative bacterial proteins formed two distinct but adjacent clusters. However, the archaeal homologues were found in multiple clusters while the plant proteins localized to two clusters. It is possible that a few gene duplication events that occurred early during the evolution of Tat family constituents were responsible for these unexpected phylogenetic characteristics (van Dijl et al., 2002; Yen et al., 2002b).
IV. OMP TRANSLOCASES OF GRAM-NEGATIVE BACTERIA A. The MTB (Fig. 6.6) The MTB consists of a complex, spanning the two membranes of the Gramnegative bacterial envelope, of 12–15 different proteins that somehow function in the energized transport of folded exoproteins from the periplasm across the outer membrane to the external milieu (Peabody et al., 2003). One of the proteins of the Klebsiella MTB complex, the PulD secretin (TC #1.B.22), is homologous to one of the constituents of the IIISP system (TC #3.A.6; Fig. 6.6; Peabody et al., 2003). PulD and its homologues form dodecameric ring structures with large, central, gated pores (internal ˚ ; Chami et al., 2005; Collins et al., 2001; Schmidt diameters of 50–100 A et al., 2001). Another constituent of the MTB (the PulE ATPase) is homologous to an ATPase (VirB11) of the IVSP complex (TC #3.A.7). Otherwise, homology of the distinct protein constituents of these two translocases has not been established. Their constituents share few structural and functional features and probably evolved independently of each other.
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MTB (II)
PulD
PulS
PulC Pul GJF KN
PulE
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FIGURE 6.6 MTB, a type II outer membrane SP in Klebsiella species. PulE is an ATPase; PulD comprises the outer membrane dodecameric secretin complex with PulS serving as a lipoprotein anchor. PulC spans the periplasm and interacts with the inner membrane complex, the outer membrane secretin, and the substrate protein as it passes from the periplasm to its external destination.
However, they sometimes use common constituents as noted above, and parallels with type IV protein secretion systems have been noted (Filloux, 2004). The other constituents of the MTB are either integral constituents of the inner membrane (PulC, F, G, H, I, J, K, L, M, N, and O), a peripheral constituent of the inner membrane (PulE) or in one case, a peripheral outer membrane lipoprotein which probably functions as a secretin-specific chaperone/anchor protein (PulS; Nouwen et al., 1999). One of the inner membrane proteins (PulO) is a peptidase/N-methyl transferase that processes the pilin-like precursors of PulG, H, I, J, and K. The PulE ATP-binding ATPase/kinase exhibits an essential zinc-finger motif. Another protein, PulL, is required for PulE to associate with the membrane. These proteins probably form a trans-periplasmic complex called a ‘‘secreton’’ that (1) recognizes the substrate proteins in the periplasm, (2) energizes transport across the outer membrane, and (3) controls opening of the PulD secretin pore. Retraction and extension of the periplasmic pseudopilus, consisting in part of the PulG protein, may energize
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transport (Burrows, 2005; Vignon et al., 2003). Other proteins may be involved in secreton assembly. Substrate proteins fold in the periplasm prior to transport across the outer membrane. The secretion signal may be contained in the tertiary conformation of the native protein, or multiple signals may be present (Francetic and Pugsley, 2005). One of the V. cholerae integral MTB membrane constituents, EpsC (homologous to PulC of K. pneumoniae), has been examined both structurally and functionally (Korotkov et al., 2006). While anchored in the inner membrane, the largest part of EpsC is periplasmic, containing a so-called homology region (HR) domain and a PDZ domain. The PDZ domain probably interacts with exoproteins to be secreted, while the HR domain plays a key role in linking the inner-membrane sub-complex of the MTB to the outer membrane secretin (Korotkov et al., 2006). Thus, it is possible to visualize the mulitcomponent complex where EpsC (PulC) plays an important bridging function between the inner and outer membrane (Fig. 6.6).
B. FUP systems Fimbriae of Gram-negative and Gram-positive bacteria fall into several distinct classes, and mutiple mechanisms for their assembly have been identified (Anantha et al., 2004; Zavialov et al., 2007). Among these are the FUP systems (TC#1.B.ll), which are responsible for the biogenesis of numerous fimbriae (pili) in Gram-negative bacteria, cyanobacteria, and Deinococcus radiodurans. D. radiodurans is designated a Gram-positive bacterium, but it has an unusual dual membrane envelope (Yen et al., 2002a). Frimbriae often function as adhesins that recognize specific macromolecules, usually glycoproteins and glycolipids (Zavialov et al., 2007). The operon encoding the structural proteins of each fimbrium also encodes a fimbrium-specific periplasmic chaperone protein and a fimbrium-specific outer membrane usher protein. The latter constituents fall into one of six phylogenetic classes (Nuccio and Ba¨umler, 2007). However, the chaperone and usher proteins, in general, appear to have evolved in parallel from their evolutionary precursor proteins (Van Rosmalen and Saier, 1993). The usher proteins contain a large central domain that spans the outer membrane 24 times as b-strands, presumbaly forming a b-barrel structure (Mol and Oudega, 1996). Following translocation across the inner membrane by the Sec system, the pilus subunits are bound to the chaperone protein, preventing the self-assembly of pili in the periplasm. Interactions between the chaperone and the periplasmic domains of the usher protein release the pilus subunits, which are subsequently exported through the usher protein across the outer membrane as a prelude to pilus assembly on the outer surface of the outer membrane (Sauer et al., 2000; Thanassi and Hultgren, 2000). The mechanism by which the assembled fimbrial
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structures are exported through the usher proteins is not well understood. However, assembly involves the external surfaces of the usher proteins. Thus, these proteins are multifunctional, serving as chaperones, porins, and assembly apparatuses.
C. Autotransporter-1 (AT-1) systems Autotransporters of the AT-1 (or AT) family (1.B.12) each consists of a single protein with an N-terminal Sec-type signal peptide, a central passenger domain, and a C-terminal b-domain of 250–300 amino acyl residues (Dautin and Bernstein, 2007). Although the b-domains of different autotransporters of the AT-1 family are homologous, they are extremely diverse in sequence. Moreover, the passenger domains, which determine the functions of the exoproteins, vary tremendously in sequence and size (Loveless and Saier, 1997). They can serve as adhesins, toxins, proteases, heme receptors, and other virulence factors. These proteins are found primarily in proteobacteria, but the chlamydial kingdom and a few other Gram-negative bacterial kingdoms also have recognizable AT-1type autotransporters (Yen et al., 2002a). Following secretion across the inner membrane via the Sec system, and cleavage of the signal peptide, multiple b-domains form oligomeric ring-shaped complexes of 500 kDa in the outer membrane, thought to allow passage of the folded N-terminal domains through the channel (Veiga et al., 2002). The passenger domains, most of which are virulence factors in Gram-negative pathogenic bacteria, are either released to the environment or remain attached to the cell surface. There is still substantial controversy about the outer membrane transport mechanism (Dautin and Bernstein, 2007).
D. Autotransporter-2 (AT-2) systems A novel type of autotransporter (TC # 1.B.40) has been identified in proteobacteria and a few more distantly related Gram-negative bacteria. The prototype is the adhesin protein YadA of Yersinia enterocolitica (El Tahir and Skurnik, 2001; Grosskinsky et al., 2007; Roggenkamp et al., 2003). Rather than having 14 or 15 amphipathic b-strands as is true for the better characterized AT-1 autotransporters described above, YadA contains a Cterminal putative transport domain of only about 70 residues consisting of four amphipathic b-strands. This ‘‘transporter’’ domain is joined to the Nterminal passenger domain by a coiled-coil linker (Cotter et al., 2005). This linker is essential for stability and translocation of the passenger domain through the outer membrane. The structures of the transporter domains and the nature of the passenger domains are not yet fully defined. However, the available evidence suggests that the passenger domains, the linker, and possibly the AT-2
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domains, arose by intragenic duplication of segments of defined size, creating multiple repeat units in the proteins. The repeat units vary in size from 7 to about 50 amino acyl residues (Kim et al., in press). A single AT-2 protein may have multiple copies of as many as three different types of repeat units, where the largest repeats are near the N-termini of the passenger domain and the smallest is near the C-termini of this domain, overlapping the linker region connecting the passenger domain and the AT-2 domain (Kim et al., in press). In spite of their sequence diversity, most of these proteins may serve as adhesins (Scarselli et al., 2006; Tang et al., 2007). Secondary functions include host cell invasion, immunoglobulin binding, serum resistance, and hemeagglutination.They are found in a large range of Gram-negative bacteria and their phage. As for AT-1 family members, AT-2 proteins are exported to the outer bacterial surface by a still controversial mechanism.
E. The Intimin/Invasin or Autotransporter-3 Systems The Intimin/Invasin (Int/Inv) or Autotransporter-3 (AT-3) family (TC # 1.B.54) of adhesins are outer membrane (OM) proteins found in strains of Yersinia spp. (Inv), pathogenic E. coli (Int), and other proteobacteria. These homologous proteins mediate attachment to and invasion into their host cells. Intimins/Invasins are translocated from the cytoplasm across the IM via the Sec-translocase (TC # 3.A.5), and are related to each other both in terms of sequence and structure (Gal-Mor et al., 2008; Adams et al., 2004; Wentzel et al., 2001). Both intimins and invasins expose structurally similar domains on the bacterial cell surface resembling an extended rigid rod made of domains similar to eukaryotic members of the immunoglobulin superfamily. The carboxy-termini have a folding topology related to C-type lectinlike receptor-binding domains, which are separated from a membraneembedded N-terminal domain by several tandem Ig-like repeats, four in invasins and three in intimins. With >36% identity existing within the first 500 amino acids of most of these proteins, the conserved N-terminal domains are believed to form porin-like beta-barrels in the OM. These domains are probably used to export the C-terminal passenger domains across the outer bacterial cell membrane (Adams et al., 2004; Batchelor et al., 2000; Gal-Mor et al., 2008). The extracellular C-terminus of an Int/Inv is responsible for receptor binding to Tir (translocated intimin receptor) and b1 integrin, respectively. Intimins are surface proteins of enteropathogenic and enterohemorrhagic E. coli that promote intimate bacterial adhesion associated with attaching and effacing lesion formation (Adams et al., 2004; Gal-Mor et al., 2008). The Tir binding sites of intimins are located at the opposite side of the C-terminal lectin-like domain. Invasins lack the short alpha-helix
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(residues 904–909 of intimin) involved in Tir binding (Luo et al., 2000). Invasins bind to high-affinity members of the beta1 family of integrins to mediate bacterial entry into eukaryotic cells (Adams et al., 2004). Intimin-mediated adhesion of bacterial cells to eukaryotic target cells can be mimicked by surface display of a short fibrinogen receptor binding peptide. Intimate bacterial adhesion associated with attaching and effacing lesion formation is promoted by intimin. Intimin targets the translocated intimin receptor (Tir) which is exported by the bacterium and integrated into the host cell membrane. Tir is introduced into the host cell membrane via a type III protein secretion/translocation system. For both Intimins and Invasins, a C-terminal fragment of ~190aa is sufficient for function, although no significant sequence similarity is observed. At least five different subtypes of intimins have been described. They are integrated into the E. coli OM by their amino-terminal regions, while the C-terminal 280 amino acids are surface exposed (Batchelor et al., 2000; Wentzel et al., 2001). The EaeA intimin from E. coli strain EHEC O157:H7 is 939 amino acyl residues long. It contains an N-terminal transporter domain, which resides in the bacterial cell OM and promotes translocation of the four C-terminally attached passenger domains. The cell binding activity of EaeA has been localized to its C-terminal 280 residues. It is assumed that the N-terminal 550 residues of intimins form porin-like structures and are folded into antiparallel beta-barrels. The entire extracellular segment forms an elongated and relatively rigid rod made up of three immunoglobulin-like domains and a C-terminal lectin-like domain which interacts with the receptors. This domain resides on a rigid extracellular arm, which is most likely anchored to the amino-terminal transmembrane domain through a flexible hinge that includes two noncontiguous conserved glycine residues. They allow mechanical movement between the extracellular rod and the bacterial OM (Wentzel et al., 2001; Luo et al., 2000). Intimins form ring shaped structures with a diameter of 7nm and a channel which can accommodate peptide chains, but not fully folded passenger domains (Adams et al., 2004). The AT-3 (Int/Inv) family is just one of many distinct secretion mechanisms used by pathogenic gram-negative bacteria for the efficient surface display of binding domains which specifically interact with their complementary receptors on host cell surfaces (Saier, 2007; Wentzel et al., 2001). While not much is known about the secretion mechanisms of Int/Inv, the passenger domains may be secreted by an autotransporter-like mechanism (Gal-Mor et al., 2008).
F. Two-partner secretion (TPS) systems Each TPS system (TC # 1.B.20) is composed of a substrate protein and a transport protein that are usually encoded by two neighboring genes (Jacob-Dubuisson et al., 2001). Although TPS homologues have not been
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identified in archaea, they have been found in bacteria and the animal, plant, and fungal kingdoms of eukaryotes (Yen et al., 2002a). Most protein substrates of bacterial TPS systems are large proteins with adhesive activities that are related to bacterial virulence (Buscher et al., 2006; Thanassi et al., 2005). They can additionally serve as toxins, hemeaglutinins, and heme and hemoglobins receptors (Aoki et al., 2005; Choi et al., 2007). The transport protein consists of a b-domain with 19 predicted amphipathic b-strands that presumably form a b-barrel channel in the outer membrane (Jacob-Dubuisson et al., 1999; Ko¨nninger et al., 1999). Both proteins are secreted to the periplasm by the Sec system, and the passenger domain (TpsA) is further exported across the outer membrane by the transport constituent (TpsB) of the binary system (Newman and Stathopoulos, 2004). The mechanistic details of protein secretion by the outer membrane transporter are still unclear. The substrate protein contains a conserved N-terminal domain of approximately 115-amino acyl residues that is specifically recognized by its cognate transport protein (Jacob-Dubuisson et al., 1997). The first member of the TPS family to be characterized was the ShlB (HlyB) protein of Serratia marcescens, which exports the ShlA hemolysin from the periplasm of the Gram-negative bacterial envelope into the external medium (Poole et al., 1988). ShlA reaches the periplasm by export from the cytoplasm via the GSP or Sec pathway. ShlB and some, but not all TPS homologues, include domains with both an outer membrane export channel and a ‘‘hemolysin activator protein’’ which activates ShlA by derivatization with phosphatidyl ethanolamine (Hertle et al., 1997). Several ShlB homologues have been functionally characterized (Hirono et al, 1997; Jacob-Dubuisson et al., 1997, 2000; Palmer and Munson, 1995). The channel activities of some of these homologues have been demonstrated (Jacob-Dubuisson et al., 1999), and topological features of these putative b-barrel porins have been studied (Gue´din et al., 2000). Specificity for particular protein substrates has been demonstrated (Jacob-Dubuisson et al., 1997). One such protein, FhaC of B. pertussis, exhibits a surface exposed N-terminus and an odd number of b-strands with large surface loops and small periplasmic loops (Gue´din et al., 2000; Ka`nninger et al., 1999; Me´li et al., 2006). Substrates of TPS family secretins include Caþ-independent cytolysins, an iron acquisition protein and several adhesins. The hallmarks of TPS systems are the presence of (1) an N-proximal module where specific secretion signals in the substrate (TpsA) protein are found, and (2) a b-barrel channel (TpsB) homologue (Jacob-Dubuisson et al., 2000). Usually, the genes encoding these two proteins occur within an operon. While transport via the GSP occurs in the unfolded state, the substrate protein may fold in the periplasm and on the periplasmic surface of the outer membrane before it is exported via the TPS porin (Jacob-Dubuisson et al., 2000).
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FhaC of B. pertussis, the TpsB protein that transports the TpsA partner, FHA, exhibits a surface-exposed N-terminus and 19 putative b-strands with large surface loops and small periplasmic turns as is typical of these proteins (Hodak et al., 2006; Me´li et al., 2006). Surface exposed residues and pore formation in artificial membranes have been characterized with both FhaC and the ShlB outer membrane porins. Me´li et al. (2006) reported that FhaC exhibits ion channel properties, and FhaC mutants altered for FHA transport exhibited altered ion channel activities. The N-terminal 200 residues probably form a functionally distinct domain that modulates the pore properties and may participate in FHA recognition. The C-terminal two-thirds of TpsB forms the transmembrane channel-forming b-barrel domain. A C-proximal motif (the family signature sequence) appears to be essential for pore formation (Me´li et al., 2006). FhaC recognizes only nonnative conformations of the TPS domain, and in vivo, periplasmic FHA is not folded. Interaction determinants forming the secretion signal have been identified (Hodak et al., 2006). They are found far into the TPS domain and include both conserved and variable residues, which most likely explain the specificity of the TpsA–TpsB interaction. The N-terminal domain of FhaC is involved in the FHA–FhaC interaction, in agreement with its proposed function and periplasmic localization. Proteins showing large regions of sequence similarity to established members of the TPS family have been identified in Gram-positive bacteria, yeast, plants, and animals. They clearly share homologous domains. In Gram-negative bacteria, the two-partner secretion (TPS) pathway is dedicated to the secretion of large, mostly virulence-related proteins. The secreted TpsA proteins carry a characteristic 250-residue-long N-terminal ‘‘TPS domain’’ essential for secretion, while their TpsB transporters specifically recognize their respective TpsA partners and mediate their translocation across the outer membrane. In Gram-negative bacteria, most surface-associated proteins are present as integral outer-membrane proteins. Exceptions include the Haemophilus influenzae HMW1 and HMW2 adhesins and a subset of other proteins secreted by the TPS system. HMW1 forms hair-like fibres on the bacterial surface and is usually present as pairs that appear to be joined together at one end. HMW1 is anchored to the multimeric HMW1B outer membrane translocator, resulting in a direct correlation between the level of surface-associated HMW1 and the quantity of HMW1B in the outer membrane. Anchoring of HMW1 requires the C-terminal 20 amino acids of the protein and is dependent on disulphide bond formation between two conserved cysteine residues in this region (Buscher et al., 2006). The immediate C-terminus of HMW1 is inaccessible to surface labeling, suggesting that it remains buried in HMW1B. These observations may have broad relevance to many proteins secreted by the TPS
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system, especially given the conservation of C-terminal cysteine residues among surface-associated proteins in this family.
G. OMP insertion porins (OmpIP) Gram-negative bacterial OMPs are assembled from the periplasm into the outer membrane in a process that is poorly understood. Large (800 aas) OMPs, complexed with several others, appear to play crucial roles. Omp85 of Neisseria species (TC #1.B.33.1.1) and the D15 antigen of Haemophilus species (1.B.33.1.2) were the first to be characterized. These proteins are distantly related to the TpsB proteins discussed in the preceding section. These large constituents are also distantly related to the chloroplast import-associated b-barrel channel protein, IAP75 (TC #1. B.33.2.1), a constituent of the chloroplast envelope protein translocase (CEPT or Tic-Toc) family (TC #3.A.9). IAP75 has been shown to be a b-barrel porin in the outer membrane of plant chloroplasts (Ertel et al., 2005; Gentle et al., 2005). Another homologue is the yeast mitochondrial sorting and assembly machinery (SAM) constituent, SAM50 (Kozjak et al., 2003). The SAM complex in yeast mitochondria consists of at least three proteins (Kozjak et al., 2003; Milenkovic et al., 2004; Wiedemann et al., 2003) and is required for the assembly of outer membrane b-barrel proteins in mitochondria. The functionally characterized homologue in Neisseria meningitidis, Omp85, is essential for bacterial viability (Gentle et al., 2004). It has a two-domain structure with an N-terminal periplasmic domain rich in POTRA repeat sequences and a C-terminal domain that forms an integral outer membrane b-barrel (Gentle et al., 2005). Unassembled forms of various OMPs accumulate when Omp85 is depleted (Voulhoux et al., 2003). Moreover, immunofluorescence microscopy showed decreased surface exposure of OMPs, particularly at the cell division planes. Homologues of Omp85 are present in all Gram-negative bacteria examined (Voulhoux et al., 2003). Generally in Gram-negative bacteria, LPS or its precursors and phospholipids (PLs) destined for the outer membrane are made in the inner membrane. Genevrois et al. (2003) have reported that the Omp85 structural gene in Neisseria is cotranscribed with genes involved in lipid biosynthesis. Depletion of Omp85 results in accumulation of LPS and PL in the inner membrane and loss from the outer membrane. The effects on lipids were reported to precede the effects on OMP (PorA and Opa) insertion, suggesting that the latter effects were secondary to the effects on LPS and PL translocation (Genevrois et al., 2003). However, Doerrler and Raetz (2005) came to the opposite conclusion when studying the effects of mutations in the homologous yaeT gene of E. coli. YaeT is the E. coli Omp85 orthologue. These investigators and others concluded that
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YaeT functions as a principal constituent of a complex that catalyzes protein insertion into the outer membrane (Gentle et al., 2004). A different protein, OstA or Imp (784 aas in E. coli; TC #1.B.42) may mediate LPS export (Bos et al., 2004; Hu and Saier, 2006). Normally OMPs are translocated into the periplasm via the Sec translocase (TC #3.A.5). They are believed to fold in the periplasm before being inserted into the outer membrane. Folding is stimulated by the small periplasmic chaperone protein SurA (P21202), and by a peptidyl prolyl cis-trans isomerase (PPIase) called Rotamase C or parvulin (P0A9L5). Two other periplasmic/OMPs, Skp (OmpH; HlpA; P11457) and another PPIase, FkpA (P45523) also function in this capacity (Missiakas et al., 1996). Still other proteins may be involved. It is even possible that an energy source will prove to be required. In E. coli, a multiprotein complex has been shown to be required for outer membrane biogenesis (Wu et al., 2005). This complex includes YaeT, a lipoprotein, YfgL, and atleast two other proteins, YfiO and NlpB. It is believed that the activities of these proteins provide the primary function for OMP assembly. The specific biochemical roles of the individual protein constituents have recently been elucidated (Kim et al., 2007; Malinverni et al., 2006; Sklar et al., 2007). YaeT of E. coli has one or more polypeptide transport-associated (POTRA) domains (Robert et al., 2006). The crystal structure of a periplasmic fragment of YaeT (Kim et al., 2007) revealed the POTRA domain fold and suggested a model for how POTRA domains can bind different peptide sequences, as required for a machine that handles numerous b-barrel protein precursors (Bos et al., 2007). Analysis of POTRA domain deletions showed which are essential and provided a view of the spatial organization of this assembly machine (Kim et al., 2007). The pore-forming regions of YaeT proteins are restricted to the C-termini (Stegmeier and Andersen, 2006). Based on phylogenetic analyses, the pore-forming domains display different evolutionary relationships than the N-terminal domains. The N-terminal domains are involved in gating of the pore, recognize the substrate proteins, participate in complex formation, and take part in homo-oligomerization. The differences in the phylogenies of the two domains are explained by different functional constraints acting on the two regions. The poreforming domain is divided into two functional regions where the distal C terminus forms a dimeric pore. Based on functional and phylogenetic analyses, an evolutionary scenario that explains the origin of the contemporary translocon has been proposed (Bredemeier et al., 2007). YaeT of E. coli is essential for outer membrane biogenesis. However, a homologue to YaeT is present in E. coli denoted YtfM (Stegmeier et al., 2007). Like YaeT, YtfM is predicted to consist of an amino-terminal periplasmic domain and a membrane-located carboxy-terminal domain. Nevertheless, YtfM is nonessential, and lack of the protein has no effect on
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outer membrane composition and integrity. The only observable phenotype was reduced growth (Stegmeier et al., 2007). Its molecular function has yet to be defined.
V. PROTEIN TRANSLOCASES OF EUKARYOTIC ORGANELLES In discussing the bacterial protein secretory complexes and integral membrane insertases, referred to in preceding sections, brief reference was made to homologues in eukaryotic organelles. These bacterial proteins included the YidC inner membrane insertase and the Omp85/YaeT outer membrane component among others (Chan and Lithgow, 2008). In chloroplasts, the Tat and Sec systems are also functional (Dalbey and Kuhn, 2000; Mu¨ller and Klo¨sgen, 2005; Robinson and Bolhuis, 2004; Steiner and Lo¨ffelhardt, 2005). Moreover, many protein constituents of the chloroplast-specific translocases have homologues in cyanobacteria. It seems clear that the chloroplast-bacterial connection is much tighter than the mitochondrial-bacterial connection, reflecting their relative dates of divergence. The protein translocating systems that have evolved in eukaryotic organelles are usually more complex than those in prokaryotes with several novel accessory proteins providing peripheral functions. Moreover, additional systems have apparently evolved to provide novel functions (Dolezal et al., 2006). Examination of the complexities and interrelated features of these organellar systems provides a more comprehensive view of complex molecular organization than would be possible if these systems were examined only in the more streamlined prokaryotes (Kutik et al., 2007).
A. MPT complexes (TIM-TOM; TC #3.A.8; Fig. 6.7) The MPT, which brings nuclearly encoded preproteins into mitochondria, is very complex with numerous identified protein constituents that comprise at least five translocons, two in the outer membrane: Tom (Tom ¼ outer membrane translocase; Tom40/70/22/20) and Sam (Sam50/ Sam35/Mas37), and three in the inner membrane, Tim23 (Tim23/17/ 44/50/Hsp70/Pam16/Pam18/Mge1; PAM ¼ presequence-associated import motor); Tim22 (Tim22/54/18), and Oxa1p (TC #2.A.9; Neupert and Herrmann, 2007; Wiedemann et al., 2004; see Figs. 6.7 and 6.8). These systems function in conjunction with several chaperone proteins (Rehling et al., 2004). The Tom consists of import receptors and the proteins of the Tom channel complex. Integral outer membrane receptor proteins are called Tom70, Tom22, and Tom20. Of these receptor proteins, only Tom22 is
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Protein Translocases in Mitochondria
Cytosolic preproteins
TOM complex
Tom Tom 20
Cytosol
Tom22
Outer membrane
Tom40 5 76
Oxa1 complex 8 10 12
xxx
Tim 22
Tim Tim 17 23
Tim xxx
TIM22 complex
Oxa 1
Tim44 xxx E
TIM23 complex
Oxa 5
Intermembrane space Inner membrane Matrix
xxx E
Mitochondrial translation products
xxx E
xxx
FIGURE 6.7 Protein translocases in mitochondria. Nuclear-encoded proteins in the cytoplasm dock to the translocator in the outer membrane (TOM) complex receptor before being translocated through that membrane. Intermembrane chaperones facilitate transfer to the translocators in the inner membrane, the TIM22 and TIM23 complexes, each specific for a different subset of substrate proteins. These two complexes transport proteins across or allow integration into the inner mitochondrial membrane. Transfer to the matrix is facilitated by chaperone proteins. The Oxa1 complex integrates a subset of the latter proteins as well as some mitochondrially-encoded proteins (mitochondrial translation products) into the inner membrane. The sorting and assembly machinery (SAM), for integration of outer membrane b-barrel proteins, is not shown (see Fig. 6.8).
essential for protein import. The receptor complex delivers the substrate proteins to the outer membrane channel consisting of five hydrophobic proteins, Tom40, Tom38, Tom7, Tom6, and Tom5. Tom40 is the core oligomeric subunit of this channel. It forms a b-stranded, cation-selective, high conductance pore that specifically binds to, and transports mitochondrial-targeting peptides. The inner pore diameter has been esti˚ . The small Tom proteins may function in mated to be about 22 A regulatory or chaperone capacities and are not essential (Rehling et al., 2003, 2004). The membrane-embedded C-terminal segment of TOM40 constitutes the pore. It also serves as a receptor, recognizing the preprotein substrate (Neupert and Herrmann, 2007; Suzuki et al., 2004). The TOM complex can apparently function independently of the two primary TIM complexes. It transports proteins from the cytoplasm to the intermembrane space (Herrmann, 2003). Conserved, intraprotein,
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β-Barrel OMP Insertases Mitochondria
Gram-negative bacteria
Cytosol OM IMS
IM Matrix
TOM
TOB
Omp85 SutA
sTIM
OM
Periplasm
Skp
Sec
Im Cytosol TiBS
FIGURE 6.8 Comparison between b-barrel insertion of outer membrane proteins (OMPs) by the mitochondrial SAM (TOB; left) and the Gram-negative bacterial OmpIP system (right). The primary channel-forming proteins in both systems (Tob55 in yeast mitochondria; Omp85 in Neisseria species) are demonstrably homologous. IM, inner membrane; IMS, intermembrane spore; OM, outer membrane. Skp and SurA are periplasmic chaperone proteins. See text for further clarification.
hydrophilic targeting sequences, different from matrix targeting sequences, are involved. Targeting translocation across the outer membrane may be independent of ATP and the pmf, but subsequent transport steps require ATP. About 30% of mitochondrial proteins lack matrix targeting sequences. They can be present in the outer membrane, the intermembrane space, and the inner membrane. These proteins may be imported initially via the TOM complex, but their transport across or into the inner membrane is achieved by two independent systems, each with a different subset of targeted proteins. The Tom complex distinguishes between b-barrel proteins and other types of preproteins, thus playing an active role in the transfer of preproteins to subsequent translocases for insertion into the correct mitochondrial subcompartment (Sherman et al., 2006). Mia40p and Erv1p are probably chaperone-like redox components of a translocation pathway for the import of cysteine-rich proteins into the mitochondrial intermembrane space. Oxidized Mia40p contains three intramolecular disulfide bonds. One disulfide bond connects the first two cysteine residues in a CPC-motif. The second and the third bonds belong to the twin Cx9C-motif and bridge the cysteine residues of two
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Cx9C-segments. In contrast to the stabilizing disulfide bonds of the twin Cx9C-motifs, the first disulfide bond is easily accessible to reducing agents. Partially reduced Mia40C, generated by opening of this bond, as well as fully reduced Mia40C, is oxidized by Erv1p in vitro, and mixed disulfides of Mia40C and Erv1p can be formed (Grumbt et al., 2007). Thus, these proteins probably facilitate disulfide bond formation in substrate proteins. The two inner membrane channel-forming complexes are both multicomponent. One, the Tim23 complex, consists of at least two integral membrane Tim proteins, Tim23 and Tim17, as well as peripheral membrane motor proteins, Tim44, Pam16, and Pam18. In this complex, other motor components (Tim14 and Mge1) are required (Mokranjac et al., 2003a,b; Rehling et al., 2004; Truscott et al., 2003). Tim23, possibly together with Tim17, exhibits channel activity. Two ATP-dependent matrix chaperone proteins (mHsp70 and mGrpE) have been suggested to function together with Tim44 to drive active uptake. Tim44 (with or without the chaperone proteins) may function as an ATP-driven import motor that pulls the precursor polypeptide chain through the Tim23 channel into the matrix. The Tim23 complex imports presequence-containing matrix proteins as well as presequence-containing inner membrane monotonic (1TMS) proteins. The latter can laterally diffuse out of the channel into the lipid bilayer (Herrmann, 2003). The second inner membrane channel-forming complex consists of at least three integral membrane proteins, Tim22, Tim54, and Tim18. The Tim22 complex has been purified and shown to insert inner membrane proteins by a twin-pore translocase that uses the pmf as the exclusive energy source and a half-of-sites mechanism (Rehling et al., 2003, 2004). The polytopic substrate proteins of the Tim22 complex (including Tim22 and Tim23) lack typical presequences and instead have internal targeting signals. Tim22 is a dynamic, ligand-gated, high conductance, slightly cation-selective channel, solely active in the presence of its cargo protein (Peixoto et al., 2007). The Tom and Tim proteins have homologues in yeast, other fungi, animals, plants, and various unicellular eukaryotes. Some constituents are homologous between these eukaryotes, but others are nonhomologous (Lister et al., 2007). Moreover, the Tim23, Tim17, and Tim22 proteins within a single organism are homologous to each other. Some of the inner membrane proteins are translocated into the matrix via the Tim23 complex and then, following cleavage of its first signal sequence, they are targeted to the Oxa1 complex (TC #2.A.9). Moreover, most membrane proteins that are translated within the mitochondrial matrix are directly inserted into the inner membrane by the Oxa1 complex. Another group of inner membrane proteins is directly targeted to the inner membrane in a pathway requiring intermembrane protein
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complexes as well as the integral inner membrane Tim22 complex. While the proteins that use the Tim22 complex are generally of eukaryotic origin (e.g., MC family members (TC #2.A.29)), those that use the Oxa1 complex are usually of bacterial origin (Chacinska et al., 2002; Herrmann, 2003). Most MCs (2.A.29) generally lack N-terminal targeting sequences, and those that have them do not require them for proper insertion. Instead, they become partially organized into partially assembled forms within the translocon. They present to the translocon noncontiguous targeting signals scattered throughout the protein sequence (de Marcos-Lousa et al., 2006). A detailed multistep process has been proposed by de MarcosLousa et al. (2006). While the Tim23 import system depends on a single water-soluble intermembrane protein, Tim50 (Geissler et al., 2002; Yamamoto et al., 2002), the Tim22 import system depends on two distinct water-soluble protein complexes that are present in the intermembrane space. One contains the essential Tim9 and Tim10 proteins and mediates transport of cytosolically synthesized integral inner membrane proteins including the metabolite carrier proteins from the outer to the inner membrane. The other complex includes the Tim8 and Tim13 proteins and mediates import of a different subset of integral inner membrane proteins. These two intermembrane complexes deliver substrate proteins to the Tim22 complex. Thus, multiple pathways are proposed for transfer of proteins across the intermembrane space, for transfer across the inner membrane, and for insertion into the inner membrane (Fig. 6.7).
B. The CEPT complex (Tic-Toc; TC #3.A.9; Fig. 6.9) The vast majority of chloroplast proteins are encoded within the nucleus of the plant or algal cell. These proteins are made as preproteins on cytoplasmic ribosomes and are then targeted to the appropriate organellar subcompartment. Many of the proteins that comprise the translocation apparatus in the envelope and thylakoid membranes of the chloroplast have been identified. A single assembly is thought to catalyze translocation across the two-membrane envelope, and the protein components of the envelope that have been identified and sequenced appear to be unique (Schuneman, 2007). By contrast, translocation across the thylakoid membrane may occur via three or four pathways. One of these pathways involves ATP hydrolysis and proteins of the Type II GSP (IISP; TC #3.A.5; Schleitti and Soll, 2005). The SecY-dependent thylakoid membrane translocase is therefore not part of the translocase included under TC #3.A.9. A second thylakoid membrane translocase is GTP-dependent and includes proteins homologous to eukaryotic and bacterial SRP (TC #3.A.5; Steiner and Lo¨ffelhardt, 2005). This system probably uses the SecY system. A third transthylakoid membrane translocation pathway is pmf-dependent but
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ATP- and GTP-independent. This is the Tat or VSP (TC #2.A.64) system (Robinson and Bolhuis, 2004). Preproteins may be recognized at the outer envelope and translocated in a single step across the outer and inner membranes through contact zones where the two membranes are maintained in close apposition. The targeting signal for envelope translocation is in the N-terminal bipartite ‘‘transit sequence.’’ The N- and C-terminal portions of this sequence contain chloroplastic and intraorganellar targeting information, respectively. Translocation to the stroma occurs in at least two steps and requires the hydrolysis of both ATP and GTP. Subsequently, the transit sequence is removed in the stromal compartment. In addition to chaperone proteins, four proteins of the outer chloroplast membrane translocase (TOC) and seven proteins in and associated with the inner chloroplast membrane translocase (TIC) of the chloroplast envelope import apparatus have been identified. The main Toc proteins (Toc(IAP)34/36), Toc(IAP)75 and Toc(IAP)86/159 or 160) are believed to form a recognition and translocation complex in the outer membrane (Fig. 6.9; Becker et al., 2004; Tu et al., 2004; Wallas et al., 2003). IAP34/36 and IAP86/160 are related to each other in sequence and possess cytoplasmically exposed GTP-binding sites. They are receptor GTPases. IAP34/36 and IAP86/160 each represents a single gene product. The ratios of Toc75:Toc34:Toc159 are 3:3:1 (Kikuchi et al., 2006). The protein translocons of plastid envelopes in roots and leaves include constituents of both the Tics and the Tocs that are tissue specific (Vojta et al., 2004). While the Tic proteins appear to be relatively stable, several Toc subunits seem to have a high rate of turnover (Vojta et al., 2004). A. thaliana has two homologues of Toc159 (Toc120 and Toc132) that may serve as receptors for alternative Toc159-independent import pathways. Toc75 (also called OEP75) forms an outer membrane porin consisting largely of b-structure that may serve as the OMP-conducting channel. It is distantly related to Gram-negative bacterial OMPs of the YaeT family (TC #1.B.33) and the TPS family (TC #1.B.20). Toc75 has one sequenced homologue in the blue green bacterium, Synechocystis (22% sequence identity). The Synechocystis protein is located in the outer membrane of the cyanobacterium and forms a voltage-gated, high conductance channel with high affinity for polyamines and peptides in reconstituted liposomes. Toc34/36 and Toc86/160 have sequenced homologues in many if not all plants. They also have distant homologues in bacteria and slime molds. Toc75 of the pea chloroplast and alr2269 of the cyanobacterium, Nostoc PCC7120, which are homologous throughout their lengths, consist of two domains. The N-terminal domains function in recognition and complex assembly while the C-terminal domains provide the b-barrel pore. The pore is modulated by the N-terminal domain (Ertel et al., 2005).
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Protein translocases in chloroplasts
TOC64
P
GTP P TOC159 GTP
Cytosol
TOC34
TOC64
OE
TOC15 TOC64
IES
TIC40
TIC120
TIC22
IE TIC55 TIC110
TIC22 NADH
FNR
Stroma
FIGURE 6.9 Schematic view of the translocases in the outer chloroplast membrane (TOC; top) and the inner chloroplast membrane (TIC; bottom). Proteins from the cytoplasm dock to the TOC receptor and are translocated through the TOC75 channel. They may be further translocated via the TIC system across in inner membrane. See text for details.
The Tic proteins include Tic110, Tic44, Tic22, and Tic20. Tic110 (IEP110; IAP100) is a 996 aa protein with one or two probable N-terminal, hydrophilic TMS(s). They form oligomeric channels in the inner membrane. Tic110 is also called PIRAC (protein-import-related anion channel). It is a 50-pS anion channel that becomes inactivated during protein
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transport via a mechanism that requires both a functional transit peptide in the transported protein and stromal ATP. It is believed to be the protein import channel in the inner chloroplast membrane (van den Wijngaard and Vredenberg, 1999; van den Wijngaard et al., 1999). Other Tic components, Tic22, Tic20, and Tic55 may function in preprotein recognition/conduction via the Tic110 channel. Tic22 and Tic20 have homologues in various plants and in Synechocystis sp. (286 aas, D64003, and 160 aas, D90906, respectively). The driving force for inner membrane translocation may involve ATP hydrolysis by stromal chaperones, Hsp70, ClpC, and Cpn60. Several other Tic subunits are believed to function in regulation (Schu¨nemann, 2007). The Tic and Toc complexes in the inner and outer membranes, respectively, may form independently, but they probably form a single supercomplex in the presence of a substrate preprotein by forming contact sites between the two membranes. Some evidence suggests that each complex can function in protein transport independently of the other when contact sites are disrupted. However, even then, cooperative interactions probably coordinate their activities under all conditions (Schleiff and Soll, 2005; Schnemann, 2007).
VI. COMPARISONS AND OVERVIEW Table 6.3 compares the properties of the four primary SP systems involved in inner membrane secretion in Gram-negative bacteria. The Tat system is tabulated separately for clarity. Each of these systems apparently evolved independently of each other, even though they exhibit overlapping properties and occasionally share one or two homologous protein constituents. Type I systems (ABC plus MFP and OMF proteins) consist of 3–4 protein constituents. Type II systems as defined here include the Sec or Tat system for inner membrane transport plus the MTB or a protein-specific translocase for transport across the outer membrane. Sec systems consist of 7–10 constituents. They transport proteins across or insert proteins into the cytoplasmic Gram-negative or Grampositive bacterial cell membrane (Cao and Saier, 2003). The E. coli Tat system consists of four dissimilar protein constituents, but three of these proteins are homologous and of similar sizes with the same topology. Tat systems in other bacteria can be much simpler with only two nonhomologous constituents (Yen et al., 2002b). Nevertheless, multiple subunits of TatA/B homologues generate the oligomeric pore structure (Mangels et al., 2005; Mu¨ller, 2005; Sargent et al., 2001). The MTB includes 10–12 essential constituents for transport across the outer membrane while the substrate-specific outer membrane translocases each usually consists of a single protein. Both type III and type IV systems consist minimally
TABLE 6.3 Comparison of the four principal protein export systems in Gram-negative bacteriaa Characteristics
ISP
IISP
IIISP
IVSP
Tat
1
TC#
3.A.6; 1.B.22b 10–12
2.A.64
# of constituents
10–12
2–4
3
Shared constituents
None
3.A.5; 3.A.15; 1.B.22b 7–10 (Sec; IM) 10–12 (MTB; OM) One each like type III or IV
3.A.7
2
3.A.1; 8.A.1; 1.B.17 3–4
One like type II (ATPase)
None
4
Spans the envelope (one-step transport) ATPase(s)
þ
–
One like type II (secretin) þ
þ
–
ABC-type
SecA (for Sec); GspEc (for MTB) þ
YscQ
VirB4c; VirB11c
None
þ
þ
–
SecYEG None GspD (secretin)
YscRSTU? YseJ? YscC (secretin)
VirB4, B6 VirB8, B9, B10 VirB8, B9, B10 (heterotrimer ?)
TatA/B/E None None
5 6 7 8 9
ATPase homologues of dissimilar function IM pore Transperiplasmic OM pore
– ABC-type OMF (þMFP) OMF homotrimer
(continued)
TABLE 6.3
a b c
(continued)
Characteristics
ISP
IISP
IIISP
IVSP
Tat
10
Distribution
Bacteria
Sec: Ubiquitous MTB: Gramnegative bacteria
Bacteria
Bacteria
11
Frequent lateral transfer
Sec: ; MTB:
þ
12 13
Shuffling of constituents Protein substrate conformation
þ Unfolded
– Unfolded (Sec), folded (MTB)
þ (Path); (Fla) – Partially folded subunits
Bacteria, archaea, and some eukaryotic organelles ?
– Folded subunits
? Fully assembled enzyme complexes
IM, inner membrane; OM, outer membrane; G–, Gram-negative; Gþ, Gram-positive. The Tat system (TC #2.A.64), considered as part of the type IISP, is tabulated last for clarity. Secretins form the outer membrane channels for both MTB (IISP) and Path (IIISP) systems. GspE components of IISP systems are homologous to VirB4 and VirB11 of IVSP systems (Peabody et al., 2003).
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of about 10–12 constituents. Although these two systems share certain functional characteristics, none of the protein constituents is recognizably similar in sequence between the two systems. It is thus clear that all of these systems are distinct, complex, multicomponent systems that probably evolved independently of each other. The basis for assuming that these systems arose independently in part results from the fact that homology cannot be demonstrated for constituents of one system with those of any other except for the secretins of the MTB, which are distantly related to the secretins of IIISP systems, and the ATPases of the MTB, homologues of which are found in IVSP systems. These ATPases may be involved in assembly of the complex and/or protein export (Table 6.2). While type I, III and IV systems span the two membranes of the Gram-negative bacterial envelope and translocate protein substrates across both membranes in a single energy-coupled step, type II systems, as defined here, actually consist of two distinct, independently-functioning complexes, one (Sec or Tat) for transport across the inner membrane and one (MTB) for transport across the outer membrane. The MTB system is transenvelope presumably to allow energy coupling to transport. There are also several types of proteinspecific outer membrane export systems that probably function by energy independent mechanisms. Like Sec, Tat systems transport proteins only across the cytoplasmic membrane (Table 6.2), but unlike Sec, they transport fully folded and assembled enzyme complexes using the pmf instead of ATP as the primary energy source. Well-characterized protein translocating ABC-type (type I) systems are found primarily in Gram-negative bacteria, although ABC peptide and small protein export systems are also found in Gram-positive bacteria and eukaryotes. While Sec systems are ubiquitous, being found in every living cell in which they have been sought, MTB systems seem to be restricted to Gram-negative bacteria. Homologues of Tat systems are widespread, but they are not found in all living organisms, being absent in some bacteria, some archaea, and in yeast and animals of the eukaryotic domain. However, they are represented in each of the three primary domains of life (Table 6.2). While type III pathogenesis-related systems are present only in Gram-negative bacteria, flagellar type III systems are present in Gram-positive bacteria as well, and similarly, the type IV virulence/conjugation-related systems occur in Gram-positive bacteria as well as Gram-negative bacteria. These last mentioned systems are particularly diverse, both with respect to sequence divergence of homologous constituents and with respect to the numbers and natures of apparently nonhomologous constituents. Table 6.3 also reveals that while type III (Path) and type IV (Vir) systems have undergone frequent lateral transfer, shuffling of constituents during evolution has only been shown to occur in type I systems, not
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in types II, III, and IV systems. In type I systems, OMFs have shuffled relative to the ABC and MFP constituents, but MFPs have not shuffled relative to their cognate ABC transporters (Dinh et al., 1994; Paulsen et al., 1997b). Specific protein–protein interactions, rendering essential the coevolution of all or most protein constituents of a complex may account for these startling findings. Finally, the protein species transported by these four primary types of systems are distinguishable in that Sec, ABC, and type III systems transport unfolded or partially folded protein substrates; the MTB and type IV systems transport fully or partially folded protein subunits, and Tat systems transport fully folded and assembled enzyme complexes (Table 6.3). It is therefore clear that the predominant well-characterized protein export systems in a Gram-negative bacterium like E. coli or P. aeruginosa use different protein constituents, energy sources, and mechanisms to transport their protein substrates which are transported in different states of assembly, depending on the system (Ma et al, 2003). The poorly characterized Oxa1/YidC-type systems are believed to be energized by the pmf as are the Tat systems (Luirink et al., 2001; Yen et al., 2001; Yi and Dalbey, 2005). However, the Oxa1-mediated mode of transport and the conformation of the translocated substrates of this system have not been extensively investigated (Luirink et al., 2005). It is hoped that this treatise allows the reader to conceptualize and discriminate between the various types of protein secretory systems found in nature. It is worth briefly marveling at the remarkable functional diversity that the evolutionary process has yielded, even within a single Gram-negative bacterium. Further, studies of protein translocators in less well studied organisms (e.g., Archaea, Gram-positive bacteria, and lower eukaryotes), as well as certain eukaryotic organelles (e.g., peroxysomes, amyloplasts, and endosomes) will undoubtedly expand our appreciation of structural and functional diversity. What we now see is but the tip of the iceberg.
ACKNOWLEDGMENTS We wish to thank Mary Beth Hiller and Van T. Duong for contributions to the preparation of this manuscript. This work was supported by NIH grant GM077402.
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7 Metabolic Behavior of Bacterial Biological Control Agents in Soil and Plant Rhizospheres Cynthia A. Pielach,* Daniel P. Roberts,† and Donald Y. Kobayashi*,1
Contents
I. Introduction II. Techniques for Studying the Metabolic Behavior of Bacterial Biological Control Agents III. Impact of Soil Edaphic Factors and Indigenous Microbes on Introduced Microbes in the Soil Environment IV. Plant Influences on Microbial Metabolism in the Soil Environment V. Conclusion References
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I. INTRODUCTION Rhizobacteria are soil-borne bacteria which live on or around the roots of plants in an area referred to as the rhizosphere, a soil zone which extends a few millimeters beyond the roots. As organic materials exude from plant roots, they create a nutrient-rich environment for soil microbes to inhabit and provide energy for their metabolic activity. Thus, the * Department of Plant Biology and Pathology, Rutgers University, New Brunswick, New Jersey, 08902 { Sustainable Agricultural Systems Laboratory, USDA-Agricultural Research Service, Henry A. Wallace Beltsville Agricultural Research Center, Beltsville, Maryland, 20705-2350 1 Corresponding author: Department of Plant Biology and Pathology, Rutgers University, New Brunswick, New Jersey, 08902
Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00607-2
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2008 Elsevier Inc. All rights reserved.
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rhizosphere provides an important ecological niche for rhizobacteria and is a dynamic setting for complex interactions among and between plant and microbes (Bais et al., 2006). While the interaction between plant hosts and microbes that colonize the rhizosphere can be detrimental, as in the case of soil-borne pathogens, many bacteria are known to be beneficial to their plant hosts. It is these interactions that provide interest and promise for future directions in agriculture. For example, natural antagonists to pathogens can be useful as biological agents for the suppression or prevention of disease in plants. Other examples include, the potential use of rhizobacteria as biofertilizers, phytostimulants, or in bioremediation (Compant et al., 2005; Lugtenberg et al., 2002; van Veen et al., 1997). The use of biological agents to combat plant disease in lieu of traditional chemical methods has great appeal as we strive to protect our environment. While small scale experiments with biological control agents often show great potential, variability in disease control is often observed in larger-scale tests (Compant et al., 2005; Handelsman and Stabb, 1996). Without the prospect of better consistency in diseasecontrolling capabilities, the use of biological controls will not become cost-effective and thus will likely not gain widespread use. A major factor contributing to inconsistencies in biocontrol performances is an ‘‘ecological variability’’ (Weller, 1988) that results from a dynamic and heterogeneous environment influencing the metabolic behavior of bacterial populations in soil. Without a better understanding of how ecological factors influence mechanisms of biocontrol, strategies to circumvent biocontrol inconsistencies will not be forthcoming. Considerable effort has been made in defining specific traits expressed by biocontrol agents that contribute to disease suppression. For example, colonization of plant parts is thought be an important trait to almost all biocontrol interactions (Compant et al., 2005; Haas and De´fago, 2005; Lugtenberg et al., 2001; Weller, 1988). Other traits include those associated with various mechanisms of biocontrol, which generally fall into four categories: (1) competition for nutrients; (2) production of antibiotics or other inhibitory molecules; (3) predation and parasitism; and (4) induction of plant defense pathways (Compant et al., 2005; Handelsman and Stabb, 1996). As a result of intensive characterization involving a broad range of experimental systems, significant advances have been made that improve our understanding of biocontrol mechanisms at the genetic and molecular levels. However, as represented by only a few cases (Haas and De´fago, 2005; Kiely et al., 2006), much less is know about environmental conditions and signals that induce biocontrol activity in rhizobacteria. In association with our lack of knowledge regarding environmental stimuli that induce expression of biocontrol activity, there has been relatively little effort directed at determining the importance of the metabolic energy status of biocontrol agents, or the impact of environmental
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conditions on the metabolic energy status within the context of biocontrol interactions. The metabolically active portion of bacterial populations are considered to be most important in beneficial interactions with plant hosts (Heijnen et al., 1995; Ramos et al., 2000; Unge et al., 1999; van Veen et al., 1997), as metabolic energy is ultimately responsible for expression of traits required for such activities (Crowley et al., 1996; Dowling and O’Gara, 1994; Srenson et al., 2001). Similar to the variable performances inconsistencies observed with biocontrols, metabolic energy status of bacteria is known to vary greatly under different conditions (Atkinson, 1977; Brennerova and Crowley, 1994; Duncan et al., 1994; Molin and Givskov, 1999). Understanding the impact of environmental conditions on the metabolic behavior, both on the expression of genes important for biological control and on the metabolic energy status of cells, is critical for achieving successful, replicable biological control (Haas and De´fago, 2005; Ramos et al., 2000; Srenson et al., 2001).
II. TECHNIQUES FOR STUDYING THE METABOLIC BEHAVIOR OF BACTERIAL BIOLOGICAL CONTROL AGENTS Methods for studying gene expression in bacterial biological control agents in association with plants have been reviewed extensively (Haas and Keel, 2003; Kiely et al., 2006; Rediers et al., 2005) and will not be discussed here. A number of methods based on bacterial growth activity have been used to determine the metabolic energy status of cells that are in soil or in association with plants (Molin and Givskov, 1999). These methods include estimation of growth rates based on colony counts from plating (Rovira and Davey, 1974); analysis of cell size and shape (Bloem et al., 1995; Givskov et al., 1994; Mller et al., 1995); estimation of DNA and protein synthesis rates based on incorporation of tritiated thymidine and leucine (Christensen et al., 1992; Sengelv et al., 2000; So¨derberg and Ba˚a˚th, 1998); and determination of rRNA content of cells (Poulsen et al., 1993). Other methods include determination of respiration rates (Winding et al., 1994), oxygen consumption (Baker et al., 2004), and the adenylate energy charge of cells (Brookes et al., 1983; Contin et al., 2001; De Nobli et al., 2001). Molecular methods are available that determine and differentiate the metabolic energy status of specific, introduced bacterial populations from that of indigenous microflora. These include methods based on fluorescent antibodies and rRNA probes (Amann et al., 1995; Assmus et al., 1995; Christenson and Poulsen, 1994; Hahn et al., 1992, 1997; Ramos et al., 2000). Reporter systems are particularly well suited for assessment of the metabolic energy status of specific microbial strains, as demonstrated by bioluminescence- and green fluorescent protein (gfp)-based systems (Kiely et al., 2006; Molin and Givskov, 1999; Ramos et al., 2000; Unge et al., 1999;
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van Elsas and van Overbeek, 1993). In these cases, the reporter can not only indicate metabolic energy status, but also determine the spatial distribution of individual cells responding to different environmental conditions.
III. IMPACT OF SOIL EDAPHIC FACTORS AND INDIGENOUS MICROBES ON INTRODUCED MICROBES IN THE SOIL ENVIRONMENT Edaphic features of soil are among the many factors known to affect the metabolic activity of its resident microorganisms. Soil consists of clay, silt, sand, and organic matter (humic material) that are clustered in aggregates of varying size and composition. These aggregates result in spatial voids of varying sizes that are filled by gases and aqueous solutions. Such variation in composition, further influenced by constant flux between liquid and gas phases, create microenvironments (Smiles, 1988; van Elsas and van Overbeek, 1993) that can individually have profound effects on localized microbial populations. Numerous factors, the most obvious being nutrients, are known to influence both metabolism and persistence of soil microbes. Bulk soil lacking influence from plant roots has been described as ‘‘grossly oligotrophic’’, with most of the reduced carbon and other organic matter found within it to be in recalcitrant forms (Poindexter, 1981; van Elsas and van Overbeek, 1993). Although reduced carbon is the primary nutrient to have limiting effects on microbial activity in most soils, other components such as nitrogen, phosphorus, and iron have also been reported to be limiting in some soils (Alde´n et al., 2001; Haas and De´fago, 2005). Availability of these and other essential inorganic nutrients have been shown to have significant impacts on survival and growth capabilities through interactions with other chemical, physical, and biological properties of the soil (reviewed in O’Hara, 2001). Abiotic soil factors, such as soil texture, pH, temperature, moisture, high osmotic, or matric tension, are known to impose stresses on microorganisms that not only impact their metabolic behavior, but also their survival (van Elsas and van Overbeek, 1993; van Veen et al., 1997). In a study by Bashan et al. (1995), the survival of Azospirillum brasilense was studied in 23 soil types representing different climatological conditions from tropical to arid zones. Of 15 physical and chemical soil parameters tested in this study, the percentages of clay, nitrogen, organic matter, and water-holding capacity were positively correlated with survival of the bacterium in soil. In contrast, the percentages of CaCO3, fine sand, and rough sand were negatively correlated with survival. The percentages of silt, pH, conductivity, K, P, and C/N ratio were found to have no effect on survival of the bacterium in soil.
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In addition to individual soil components, soil texture can also influence bacterial survival in different ways. For example, indigenous microorganisms can congregate in pores large enough to physically contain their population size, resulting in a composite of numerous, heterogeneous soil microbial communities that are each influenced by its own immediate environment (Foster, 1988; Hattori and Hattori, 1976). Pores of smaller sizes represent microenvironments that retain water longer during dry periods, preventing exposure of inhabiting microbes to desiccation stress (Foster, 1988). Pore size can also influence predation by protozoans. Small pores within soil can allow for occupancy by bacteria, thereby evading predation by excluding the larger protozoa (Postma and van Veen, 1990; vanVeen et al., 1997). Certain physical and chemical factors in soil not only influence microorganisms directly, but also influence the interactions that occur between organisms at different levels, ultimately affecting desirable processes such as biological control (Duffy and De´fago, 1997; Duffy et al., 1997; Ownley et al., 2003). In a study by Ownley et al. (2003), 16 of 28 soil factors were found to be positively correlated biological control of take-all disease on wheat by Pseudomonas fluorescens strain 2–79, including key soil factors such as pH, ammonium-nitrogen ratio, and zinc concentration. In contrast, the same study identified other soil factors, such as cation-exhange capacity, iron, and percent silt, which were negatively correlated with disease suppression. This example not only reflects the multiplicity of factors, but also the complexity by which factors influence microbial activity. A number of abiotic environmental signals are known to influence production of secondary metabolism in bacterial biocontrol agents (Haas and De´fago, 2005). In certain Pseudomonas spp., excess iron concentrations repress biosynthesis of the iron siderophores pyoverdine and pyochelin, while low oxygen tensions and low iron availability are required for hydrogen cyanide production. In P. fluorescens, biosynthesis of the antibiotics 2,4-diacetylphloroglucinol and pyoluteorin is stimulated by zinc, while production of salicylic acid is stimulated by molybdenum and magnesium. Stresses induced by salt, or by low concentrations of inorganic nutrients such as ferric iron, phosphate, sulfate, and ammonium, are known to reduce biosynthesis of the antibiotic phenazine-1-carboxamide in Pseudomonas chlororaphis (van Rij et al., 2004). These studies clearly indicate that variations between any of a number of soil factors can influence metabolic activity of microorganisms, and thus contribute to the variability that is often observed with biological control. Biological components within soils can also have tremendous impact on biocontrol agents, such as by way of predation as mentioned previously, or by competition for nutrients and space. However, indigenous soil microorganisms can also impact the metabolic behavior of biocontrol
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agents by affecting regulatory networks that control gene expression. One very good example of regulatory systems affected in different ways by indigenous soil populations is quorum-sensing, the cell density dependent regulatory mechanism that functions in a number of plant-associated soil bacteria (Pierson and Pierson, 2007). Quorum sensing is typically activated through the production of autoinducing compounds such as N-acyl homoserine lactones (AHL). Bacteria that use this regulatory system respond to the presence of the signal once a sufficient concentration is achieved, which is usually associated with a certain cell density. The biosynthesis of the antibiotic phenazine-1-carboxamide is dependent on N-acyl-homoserine lactone in P. chlororaphis and thus, the biocontrol activity of this bacterium is influenced in a cell density dependent manner (Molina et al., 2003). Bacteria that utilize quorum-sensing regulatory systems can be influenced by other bacterial species, or even plants, that produce similar signaling molecules (Pierson et al., 1998; Teplitski et al., 2000). Such heterologous cross-talk can result in gene regulation occurring prior to populations achieving cell densities originally designed to control gene expression. Alternatively, other microbial species can have an opposite effect on quorum-sensing systems, such as by producing inhibitory compounds or degrading quorum-sensing signals, thereby preventing regulation of gene expression from occurring when critical cell densities are reached (Molina et al., 2003; Morello et al., 2004; Uroz et al., 2003).
IV. PLANT INFLUENCES ON MICROBIAL METABOLISM IN THE SOIL ENVIRONMENT A number of factors released from roots and seeds, including ions, free oxygen, enzymes, and a diverse array of reduced carbon compounds, are known to influence metabolic activity of microorganisms (Bais et al., 2006; Lynch and Whipps, 1990). In addition to factors released by roots, metabolic processes of roots affect the surrounding microenvironments in a number of ways, including the solubilization of mineral nutrients, as well as the uptake of water, ions, inorganic compounds, oxygen, and reduced carbon compounds (Bais et al., 2006; Jones and Darrah, 1993; Jones et al., 2004; Patterson, 2003), which in turn influence the activity of resident microbes (Jones et al., 2004; Patterson, 2003). The rhizosphere effect represents another clear example where plant roots influence associated microbes, in which not only substantially higher populations of microbes are in association with plants than in bulk soil, but where specific microbial communities develop in association with certain plant species (Garbeva et al., 2004; Kent and Triplett, 2002).
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From the microbial perspective, the success of a bacterial colony is reflected by its ability to survive, colonize, and proliferate in its environment. A major factor in this success, or competence, relates to the presence of plant root exudates in the vicinity of the colony. These exudates provide a major source of nutrition and are the driving force behind their metabolic activity (Kraffczyk et al., 1984; Lynch and Whipps, 1990). The importance of exudates on metabolic behavior is demonstrated by the effect different host plants and species have on their bacterial residents. Significant variation exists in these exudates, both in amount and composition, among plants of different species. Even among the same plant species, variations occur based upon the environmental conditions present. Such variations result in different nutrient availability and undoubtedly influence microbial metabolic activities such as growth, cellular function and gene expression. Exudates are comprised of low molecular weight compounds such as amino acids, organic acids, carbohydrates, and other secondary metabolites, as well as high molecular weight mucilage and protein. Sugars, amino acids, and organic acids represent the most dominant of soluble reduced carbon compounds, and thus are the most influential on microbial growth (Farrar et al., 2003; Lynch and Whipps, 1990; Meharg, 1994; Whipps, 1990). Availability of these compounds, and therefore the level of influence they have on microbial metabolism, varies in a spatial manner along the root (Bringhurst et al., 2001; Jaeger et al., 1999; McDougall and Rovira, 1970). Most reduced carbon compounds are released near root tips, making this region among the most active for microbial metabolism. The amount of compounds released in root exudates is known to differ between plant species and plant age, and is also influence by environmental conditions (Curl and Truelove, 1986; Grayston et al., 1996; Walker et al., 2003). Thus, nutrient availability in exudates typically varies by a number of influencing factors. The significance of nutrient availability on successful colonization has been illustrated in studies investigating bacterial populations as they relate to carrying capacities of cucumber and pea seeds. These seeds are particularly suited to such studies due to the extreme difference in quantity, and therefore supply, of nutrients within the exudates. By way of example, a pea seed will exude nearly 3000 mg of glucose equivalents per seed within the first 24 hours after imbibition, whereas the cucumber seed will exude a mere 1 mg. Consequently, pea seeds support substantially greater growth and population sizes of colonizing microorganisms than cucumber seeds primarily due to higher levels of nutrients found in exudates (Roberts et al., 1999, 2000). Further evidence that the difference in carrying capacity between pea and cucumber is directly related to nutrient availability was provided in studies using mutant strains of Enterobacter cloacae with impaired catabolic
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capability (Lohrke et al., 2002; Roberts et al., 2000). The pfkA gene encodes for phosphofructokinase, a key step in glycolysis that is necessary for utilization of most hexose sugars except fructose. Colonization experiments showed the pfkA mutant strain of E. cloacae was significantly reduced in population levels in the cucumber spermosphere as compared with the wildtype strain. However, when exogenous fructose is supplied to the spermosphere to compensate for the nutritional deficit incurred by the mutation, the colonization ability was restored to levels comparable to the wildtype strain (Roberts et al., 1999, 2000). Along with cell population levels, the metabolic energy status of colonizing bacteria has been found to correlate directly with the exudate content. Using a bioluminescence-based reporter system, E. cloacae produces significantly more relative luminescence units (RLU) per cell on pea seed than on cucumber seed (Roberts et al., unpublished). These results indicate pea seed exudates not only support higher populations of cells, but the average bacterial cell colonizing a pea seed is more active metabolically than that colonizing a cucumber seed. Interactions between plant and microbe goes beyond mere nutritional requirements, with root exudates also serving as chemical attractants to bacteria, as well as effective antimicrobials (Brigham et al., 1999; Lugtenberg et al., 2001, 2002). Successful colonization becomes a matter of fitting the niche provided by the particular plant host and is dependent upon multiple factors. Accordingly, bacterial traits can play important roles in bacterial competence for colonization. For example, possessing flagella-driven chemotaxis, which allow the bacteria to be mobile within the rhizosphere environment, can provide a significant advantage over competing organisms. The significance of bacterial chemotaxis to root colonization, as well as its relationship with nutrient uptake, was highlighted in a study by de Weert et al. (2002). In this study, chemotaxis was found to be an important competitive colonization trait in P. fluorescens strain WCS365, as a cheA mutant deficient in flagella-driven chemotaxis was strongly reduced in root-colonizing ability. Chemotactic responses were also detected toward root exudate components, supporting the role of motility in colonization as a mechanism by which bacteria can seek out and reach nutrients exuded by roots. This and other studies (de Weger et al., 1987; Simons et al., 1996) support the role of motility in successful colonization, it should be pointed out that prior investigations have produced results which suggest no relationship between motility and root colonization (Howie et al., 1987; Scher et al., 1988). However, these conflicting findings could be explained by differences in experimental conditions as there is much support, as well as logic, behind the theory of motility enabling greater success in nutrient uptake in a competitive environment.
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Perhaps a less obvious, but quite intriguing finding is a connection between motility and biocontrol. In a study investigating colonization traits and biocontrol activity, Chin-A-Woeng et al. (2000) demonstrated that motility was required for P. chlororaphis strain PCL1391 to suppress tomato foot and root rot caused by the fungal pathogen Fusarium oxysporum f. sp. radicis-lycopersici. Prior research had identified the antibiotic phenazine-1-carboxamide as the primary mechanism of biocontrol for this disease (Chin-A-Woeng et al., 1998). However, mutants impaired in known colonization traits that included motility, but were still capable of producing the antibiotic at wildtype levels were shown to be deficient in disease suppression. The authors presumed that this lack of biocontrol related to the inability of the mutant strain to deliver the antifungal metabolite in a spatially relevant manner so as to be effective against the pathogen. This study further supports the belief that successful management of biocontrol agents will require an in-depth understanding of these microbes. As demonstrated here, characteristics which initially seem to be distinct and of no consequence to each other may in fact play a significant role in determining the biocontrol capability. Nutrient availability is not strictly a matter of what a plant root exudes, but is also dependent upon competition for those resources from other microorganisms living in the rhizosphere. Interestingly, this competition, creating a nutrient-limiting environment, can result in rhizobacterial metabolic behavior directly related to biocontrol. This has been clearly demonstrated by research involving a number of biocontrol systems. Competition for essential resources is a factor in survival of all organisms and has been recognized for several years to play an important role in biocontrol. If a pathogenic organism is out-competed by an antagonistic organism for a limited resource, it stands to reason disease suppression will occur. van Dijk and Nelson (2000) presented compelling evidence for nutrient competition with a new twist. In interactions between Pythium ultimum and the biocontrol agent E. cloacae, biocontrol does not occur by competition directly between the two microorganism, but rather indirectly that leads to inhibition of pathogen spore germination that is necessary for plant infection. Fatty acids are naturally present in the exudates of germinating seeds and act as signals for Pythium spp. spore germination. This concurrent germination strategy provides the pathogen an opportunity to infect the seeds while they are in a vulnerable state. To investigate the role of fattyacid metabolism in this process, van Dijk and Nelson (2000) focused on linoleic acid, a fatty acid known to be utilized as a nutrient resource by the biocontrol bacterium E. cloacae, as well as a signal to break fungistasis in the oomycete pathogen P. ultimum. Two different mutants of E. cloacae were constructed that were deficient in linoleic metabolism. Both mutants
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failed or were reduced in the ability to inactivate P. ultimum sporangium germination activity induced by either linoleic acid or by cottonseed exudate, which is rich in linoleic acid. Furthermore, both mutants failed to protect cotton seeds from infection in cottonseed bioassays assessing the ability of these strains to suppress Pythium seed rot. The results of this study succeed in demonstrating a mechanism, whereby E. cloacae can limit the availability of fatty acids to P. ultimum, thereby establishing competition in favor of E. cloacae. Since these findings also present persuasive evidence that this fatty-acid competition is a significant factor in the disease suppression exhibited by E. cloacae upon seed rot, they substantiate nutrient competition as an effective mode of biocontrol and provide insight into the specific manner in which these two microbes interact. Based upon these results, one might conclude that the key to effective biocontrol using E. cloacae against disease caused by P. ultimum is a straightforward matter of competitive advantage for nutrients. However, studies have demonstrated that catabolic degradation of fatty acids by E. cloacae is subject to catabolite repression. Consequently, variation in nutrient availability between spermospheres of different plant species can have a profound effect on fungal antagonistic activity and biological control. Studies by Kageyama and Nelson (2003) not only demonstrated differential efficacy of E. cloacae against Pythium damping off in various plant species, but also provided new insight into the fatty-acid mechanism of biocontrol exhibited by E. cloacae. The data obtained in this study relates the inability of E. cloacae to afford biological control to certain plant species to its inability to inactivate the stimulatory activity of compounds (e.g., fatty acids) involved in P. ultimum spore germination found in the seed exudates of those plants. The results of this study suggest that exudate composition, as opposed to overall exudate quantity, plays a pivotal role in whether fatty-acid competition between E. cloacae and P. ultimum occurs and points to the importance of E. cloacae metabolism in determining its biological control capability. As the mechanism of antagonism by E. cloacae against this pathogen has been demonstrated to be its ability to inactivate stimulatory activity of seed exudates via fatty-acid competition, this variable metabolic behavior of E. cloacae provides a basis for why differential biocontrol efficacy is observed in different plant species and further underscores the importance of nutrient availability on biological control activity. As demonstrated by the study conducted by Mark et al. (2005), differences in exudate content go well beyond effects of competition, having global effects on gene expression. Transcriptomic analysis of Pseudomonas aeruginosa showed substantial differences in gene expression in response to exudates from two distinct varieties of sugarbeet (Beta vulgaris L.). Not
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surprisingly, a significant proportion of genes with altered expression were involved with various aspects of metabolism. From the practical biocontrol standpoint, the relevance of nutrient availability is well illustrated with antibiotic production by the biocontrol agent P. fluorescens. P. fluorescens is known to be effective against the fungal pathogen P. ultimum, the causal agent of damping off. Secondary metabolism in P. fluorescens is globally regulated by the sigma factor ss in response to various stresses imposed during growth, including nutrient exhaustion or starvation (Koch et al., 2001; Sarniguet et al., 1995). A mutant strain of P. fluorescens disrupted in the rpoS gene, which encodes ss, is altered in its ability to produce three antibiotics: pyrrolnitrin, pyoluteorin and 2,4-diacetylphloroglucinol (DAPG). A mutation in the rpoS gene results in a mutant strain that no longer produces pyrrolnitrin, but overproduces pyoluteorin and DAPG compared with the wildtype strain. In studies with cucumber, this differential regulation of antibiotic production by ss results in the mutant strain having greater biocontrol efficacy against P. ultimum when compared to the wildtype strain, presumably due to increased production of the antibiotics pyoluteorin and DAPG. Not only does this differential regulation illustrate the importance of nutrient availability on bacterial metabolism, it clearly demonstrates the potential for metabolic behavior to impact biocontrol activity. In other studies with P. fluorescens, Duffy and De´fago (1999) investigated the effects of various minerals and carbon sources on the in vitro biosynthesis of DAPG, pyoluteorin and pyrrolnitrin. From a nutritional standpoint, this study provides clear evidence that antibiotic production is significantly impacted by carbon sources typically found in the rhizosphere. In culture-based studies, the authors found that the sugars glucose, fructose, and mannitol stimulated production of DAPG and pyrrolnitrin. Production of pyoluteorin was repressed by the same sugars, but induced in the presence of glycerol. However, they provide strong support for the supposition that the nutritional environment plays a major role in metabolic behavior of these bacteria and, consequently, biocontrol activity. This study, together with findings by Sarniguet et al. (1995) regarding the sigma factor ss, argues for an integral role that nutrient availability plays in bacterial metabolism and biological control. A classic example of competition for nutrients as a biocontrol mechanism is the production of siderophores for sequestering iron. Under ironlimiting conditions, certain bacteria secrete iron-chelating siderophores that have a high affinity for ferric iron, providing a competitive edge over other microorganisms (Loper and Buyer, 1991). Once siderophores have complexed with iron they can be recaptured, thus making this essential micronutrient available to the bacteria. Many rhizobacteria not only have the capacity to produce siderophores, they also have the ability to utilize exogenous siderophores produced by other rhizosphere inhabitants,
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thereby increasing their ability to obtain iron (Jurkevitch et al., 1992; Loper and Henkels, 1999). As with antibiotic production, siderophore production has been shown to be differentially affected by nutrient levels. Concurrent with their studies on antibiotic production by P. fluorescens, Duffy and De´fago (1999) investigated the effects of various minerals and carbon sources on the in vitro biosynthesis of the siderophore pyochelin. In general, they found that glucose alone or in combination with certain minerals resulted in increased production of pyochelin. This included addition of glucose to a rich nutrient medium, suggesting metabolic flow and nutrient balance influence production of siderophores and other secondary metabolites.
V. CONCLUSION The complexity of biological control is epitomized by the wide range of effects observed on rhizosphere inhabitants. The past 20-plus years of research has advanced our knowledge of biocontrol at several levels, from establishing roles for specific genes and identifying environmental factors that affect the biocontrol activity of microbial agents. However, much remains to be elucidated in order to successfully develop it into a widespread, commercially viable alternative to chemical methods. Among the many challenges include the following: understanding the metabolic behavior of rhizobacteria as it relates to various environmental conditions, the relevance of cellular metabolic energy status as it relates to expression of biocontrol traits, and the various roles that nutrient availability contributes to biocontrol activity. The development of new and more accurate molecular methods, along with increasing availability of whole genome scale tools to study microbial activity in environmental settings, should proved helpful and exciting in future efforts to meet these challenges.
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Smiles, D. E. (1988). Aspects of the physical environment of soil organisms. Biol. Fertil. Soils 6, 204–215. So¨derberg, K. H., and Ba˚a˚th, E. (1998). Bacterial activity along a young barley root measured by the thymidine and leucine incorporation techniques. Soil Biol. Biochem. 30, 1259–1268. Srenson, J., Jensen, L. E., and Nybroe, O. (2001). Soil and rhizosphere as habitats for Pseudomonas inoculants: New knowledge on distribution, activity and physiological state derived from micro-scale and single-cell studies. Plant Soil 232, 97–108. Teplitski, M., Robinson, J. B., and Bauer, W. D. (2000). Plants secrete substances that mimic bacterial N-acyl homoserine lactone signal activities and affect population density dependent behaviors in associated bacteria. Mol. Plant-Microbe Interact. 13, 637–648. Unge, A., Tombolini, R., Molbak, L., and Jansson, J. K. (1999). Simultaneous monitoring of cell number and metabolic activity of specific bacterial populations with a dual gfp-luxAB marker system. Appl. Environ. Microbiol. 65, 813–821. Uroz, S., D’Angelo-Picard, C., Carlier, A., Elasri, M., Sicot, C., Petit, A., Oger, P., Faure, D., and Dessaux, Y. (2003). Novel bacteria degrading N-acylhomoserine lactones and their use as quenchers of quorum-sensing-regulated functions of plant-pathogenic bacteria. Microbiology 149, 1981–1989. van Dijk, K., and Nelson, E. B. (2000). Fatty acid competition as a mechanism by which Enterobacter cloacae suppresses Pythium ultimum sporangium germination and dampingoff. Appl. Environ. Microbiol. 66, 5340–5347. van Elsas, J. D., and van Overbeek, (1993). Bacterial responses to soil stimuli. In ‘‘Starvation in Bacteria’’ (S. Kjelleberg, Ed.), pp. 55–79. Plenum Press, New York. van Rij, E. T., Wesselink, M., Chin-A-Woeng, T. F. C., Bloemberg, G. V., and Lugtenberg, B. J. J. (2004). Influence of environmental conditions on the production of phenazine-1-carboxamide by Pseudomonas chloroaphis PCL1391. Mol. Plant-Microbe Interact. 17, 557–566. van Veen, J. A., Overbeek, L. S., and van Elsas, J. D. (1997). Fate and activity of microorganisms introduced into soil. Microbiol. Mol. Biol. Rev. 61, 121–135. Walker, T. S., Bais, H. P., Grtewold, E., and Vivanco, J. M. (2003). Root exudation and rhizosphere biology. Plant Physiol. 132, 44–51. Weller, D. M. (1988). Biological control of soilborne plant pathogens in the rhizosphere with bacteria. Annu. Rev. Phytopathol. 73, 379–407. Whipps, J. M. (1990). Carbon economy. In ‘‘The Rhizosphere,’’ ( J. M. Lynch, Ed.), pp. 59–98. Wiley Interscience, New York. Winding, A., Binnerup, S. J., and Srenson, J. (1994). Viability of indigenous soil bacteria assayed by respiratory activity and growth. Appl. Environ. Microbiol. 60, 2869–2875.
CHAPTER
8 Copper Homeostasis in Bacteria Deenah Osman and Jennifer S. Cavet1
Contents
I.
Introduction A. The properties of copper B. Copper requiring proteins C. Principles of copper homeostasis II. Mechanisms of Copper Trafficking and Resistance A. P1B-type ATPases B. Copper acquisition C. Copper detoxification D. Sensors of elevated copper levels E. Copper-chaperones III. Copper and Bacterial Pathogenicity IV. Copper as a Biocide V. Concluding Remarks References
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I. INTRODUCTION A. The properties of copper Copper is widely distributed in the environment; present mainly in minerals as sulphides, oxides, or carbonates, with the major ores being chalcopyrite (CuFeS2), chalcocite (Cu2S), cuprite (Cu2O), and malachite (Cu2CO3(OH)2). Copper was the first metal to be worked by human societies and is thought to have been mined for around 5000 years. The discovery that copper could be hardened with tin, to form the alloy Life Sciences, University of Manchester, Manchester, United Kingdom 1 Corresponding author: Life Sciences, University of Manchester, Manchester, M13 9PT, United Kingdom Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00608-4
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2008 Elsevier Inc. All rights reserved.
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bronze, established the Bronze Age. Following its early use to craft tools and weapons, copper continues to have many different applications, with the greatest percentage of copper currently being used for electrical equipment such as wiring and motors. Copper primarily exists in one of two oxidation states, the oxidized Cu(II) cupric form and the reduced Cu(I) cuprous form. Cu(I) and Cu(II) are the most effective monovalent and divalent ions, respectively, for binding to organic molecules and possess almost equal tendencies to form complexes with many organic ligands (Frau´sto da Silva and Williams, 1993). Cu(I) is a closed shell 3d10 transition metal ion and hence diamagnetic. As a soft Lewis acid, it tends to bind to soft bases such as thiols, hydrides, alkyl groups, cyanide, and phosphines. Cu(II) has a 3d9 configuration and is paramagnetic. As an intermediate Lewis acid it forms complexes with additional ligands to Cu(I), including sulphate and nitrate (Crichton and Pierre, 2001). Cu(I) is susceptible to disproportionation to give Cu(II) and Cu(O), while Cu(O) is readily oxidized to Cu(I) and subsequently to Cu(II) by atmospheric oxygen. The high redox potential of the Cu(I)/Cu(II) couple makes it particularly useful and adaptable for enzymes, and most copper enzymes work in the 0.2–0.8 V range enabling them to directly oxidize substrates such as superoxide, ascorbate, catechol, and phenolates (Crichton and Pierre, 2001).
B. Copper requiring proteins The use of copper in biological systems has only occurred since the release of oxygen into the atmosphere some 2.7 billion years ago, causing the oxidation of water-insoluble Cu(I) to soluble Cu(II) (Frau´sto da Silva and Williams, 1993). Consequently, copper-requiring proteins are now widely distributed amongst aerobic organisms. Copper is usually bound to proteins via cysteine, methionine, or histidine amino acid side chains (Xue et al., 2008). Cu(I) typically favors tetrahedral geometry involving sulphur donors while Cu(II) favors square planar coordination involving nitrogen donors. Due to the fact that copper can readily undergo redox cycling between Cu(I) and Cu(II), it can act as an electron donor/acceptor in the electron transport chain (e.g., in cytochrome oxidase) and in redoxactive enzymes, which use molecular oxygen as a substrate (Frau´sto da Silva and Williams, 1993). Enzymes that perform these roles can support both oxidation states of copper. All bacterial copper-requiring enzymes appear to be extracytoplasmic and are found mainly in the periplasm or embedded in the cytoplasmic membrane. Hence, with the exception of cyanobacteria that possess copper-requiring proteins within internal membrane-bound compartments, there is currently no documented metabolic requirement for copper to cross the cytoplasmic membrane and enter the cytosol (Tottey
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et al., 2005). Copper-dependent proteins in Escherichia coli include the periplasmic copper, zinc superoxide dismutase (SodC) and amine oxidase (MaoA), and the cytoplasmic membrane located NADH dehydrogenase2 (Ndh-2) and bo3-type (quinol) cytochrome oxidase (Gort et al., 1999; Osborne et al., 1999; Parsons et al., 1995; Rapisarda et al., 2002). Grampositive bacteria, devoid of a periplasm, also possess copper-requiring proteins outside the cytosol. Bacillus subtilis has copper-requiring caa3type and aa3-type (quinol) cytochrome oxidases at the cytoplasmic membrane (van der Oost et al., 1991), and a copper laccase, CotA, is present in B. subtilis spore coats (Hullo et al., 2001). Methane oxidizing bacteria switch from using an iron-requiring soluble methane monooxygenase (sMMO) to a copper-requiring particulate enzyme (pMMO) when copper is available (Kim et al., 2004). pMMO is located within internalized membranes which are thought to be derived from the periplasm (Tottey et al., 2005). Many cyanobacteria contain internal membrane-bound compartments called thylakoids which, in contrast to those found in methane-oxidizing bacteria, are discrete from the periplasm. Thylakoids are the site of both photosynthetic and respiratory electron transport which involves the copper protein plastocyanin and a caa3-type cytochrome oxidase, respectively (Tottey et al., 2005). Plastocyanin is imported via the Sec pathway for unfolded proteins, while cytochrome caa3 oxidase is membrane bound with the di-copper A site orientated inside the thylakoid lumen. Hence, cyanobacteria are currently the only bacteria with a known requirement for copper to enter the cytosol for delivery to copper-requiring proteins (Tottey et al., 2005). However, it remains possible that in other bacteria, such as E. coli and B. subtilis, copper is also routed via the cytosol to supply copper sites located outside the cytosol.
C. Principles of copper homeostasis The ability of copper to alternate between its cuprous Cu(I) and cupric Cu(II) oxidation states makes it an ideal biological cofactor. However, when unbound within a cell, redox cycling means copper is extremely toxic, largely due to its ability to catalyze Fenton chemistry, Eq. (8.1), causing the production of highly reactive hydroxyl radicals that damage biomolecules such as DNA, proteins, and lipids. The reduced form of the metal for this reaction can be generated by reaction with superoxide (or other cellular components such as low-molecular weight thiols), Eq. (8.2), with the sum of these reactions, Eq. (8.3), being referred to as the Haber–Weiss reaction (Liochev and Fridovich, 2002). Cuþ þ H2 O2 ! Cu2þ þ OH þ OH
ð8:1Þ
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þ Cu2þ þ O 2 ! Cu þ O2
ð8:2Þ
O 2 þ H2 O2 ! O2 þ OH þ OH
ð8:3Þ
Copper can also mediate toxicity by binding to adventitious sites in proteins, nucleic acids, polysaccharides and lipids, causing the displacement of native metal ions, as well as alterations to their structure and/or function. In addition, copper appears to be much more toxic under anaerobic conditions, possibly due to the reduction of Cu(II) to Cu(I), which can diffuse through the cytoplasmic membrane causing increased copper accumulation (Beswick et al., 1976; Outten et al., 2001). Bacteria must therefore achieve precise copper homeostasis to avoid copper-mediated toxicity whilst maintaining a supply of copper for copper-requiring proteins. To achieve this, copper-sensing transcriptional regulators must distinguish copper from other metal ions and in response to levels above or below a threshold value, trigger an appropriate physiological response such as copper-import, -export, or -detoxification. Furthermore, cells may restrict access to copper by channeling copper away from adventitious sites, for example using copper-chaperones to deliver copper to its targets (Tottey et al., 2005). The proteins involved in copper trafficking and resistance may also exhibit metal specificity. The way in which bacteria meet the conflicting demands imposed by copper varies depending upon environmental conditions, their adopted ecological niche and phylogeny. Well studied bacterial copper homeostatic systems include those in E. coli, Enterococcus hirae, B. subtilis, and Synechocystis PCC 6803 (Fig. 8.1). This review will attempt to summarize the various mechanisms of copper trafficking and resistance used by bacteria with an emphasis on E. coli, while the different approaches used by other bacteria will also be highlighted.
II. MECHANISMS OF COPPER TRAFFICKING AND RESISTANCE Bacteria use copper homeostasis proteins to maintain a strict cellular copper quota, which in E. coli is estimated to be about 104 atoms per cell (c. 10 mM) (Finney and O’Halloran, 2003; Outten et al., 2001). Furthermore, the extraordinarily high (zeptomolar, 1021 molar) sensitivity of the E. coli copper sensor CueR to free Cu(I), measured at less than one atom per cell, indicates that there is essentially no free cytosolic copper (Changela et al., 2003) and most copper ions in the cell must be compartmentalized or protein bound.
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FIGURE 8.1 Principal copper homeostatic and trafficking mechanisms. (A) In E. coli, the cytoplasmic copper sensor CueR triggers production of the P1B-type ATPase CopA and the multicopper oxidase CueO. CopA transports Cu(I) from the cytosol into the periplasm where CueO is proposed to convert Cu(I) to less toxic Cu(II). CueO is exported via the TAT pathway for prefolded proteins and may also contribute to copper-export. The CusR/S two component sensory system detects surplus copper in the periplasm and triggers transport across the outer membrane by the CusABC and F proteins. Ndh-2 acts as a Cu(II)-reductase. (B) In the cyanobacterium Synechocystis PCC 6803, copper is trafficked to thylakoids through the actions of two P1B-type ATPases, CtaA and PacS, and the copper-chaperone Atx1. Atx1 is presumed to acquire copper from the importer CtaA at the cytoplasmic membrane and donate it to PacS for export into the thylakoid. (C) In B. subtilis, the cytosolic copper sensor CsoR triggers copper-export by the P1B-type ATPase CopA. The copper-chaperone CopZ is thought to channel copper to CopA. (D) In E. hirae, according to the model the P1B-type ATPase CopA imports copper, which is routed to the cytosolic copper sensor CopY and to the copper-exporting P1B-type ATPase CopB by the CopZ copper-chaperone.
The metal-binding motifs within the regulatory and homeostatic proteins have atypical coordination chemistry, relative to the enzymes that incorporate copper as a cofactor, which relates to their particular functions (Finney and O’Halloran, 2003). For example, copper-chaperones (e.g., CopZ and Atx1, Fig. 8.1) must bind Cu(I) tightly enough to prevent adventitious reactions or release of the ions, whilst allowing for easy transfer of Cu(I) to target sites. They achieve this by binding Cu(I) using
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two cysteines (in a GXXCXXC motif) and Cu(I) transfer is facilitated via the formation of low-coordination-number anionic intermediates (Banci et al., 2004; Cobine et al., 2002; Finney and O’Halloran, 2003). In contrast, extracellular or periplasmic copper homeostatic proteins operate in a more oxidizing environment than the cytosol where the use of cysteines is less appropriate; for example, due to disulphide bond formation, and utilize clusters of methionines occasionally with histidine (Arnesano et al., 2003; Davis and O’Halloran, 2008; Wernimont et al., 2003) or even tryptophan (Xue et al., 2008).
A. P1B-type ATPases The most widely distributed copper-trafficking proteins in both prokaryotes and eukaryotes are the copper-transporting P1B-type ATPases, with representatives associated with both copper-uptake and -export (Fig. 8.1). The P1B-type ATPases are a subgroup of the P-type family of ATPases (Axelsen and Palmgren, 1998), so called because an invariant aspartate residue in the conserved motif DKTGT becomes transiently phosphorylated during the reaction cycle (Pedersen and Carafoli, 1987). P1B-type ATPases are known that transport a range of metal ions including cadmium (Tsai et al., 1992), zinc and lead (Rensing et al., 1997, 1998), cobalt (Rutherford et al., 1999), and silver (Gupta et al., 1999). Phylogenetic studies have led to a further sub-division into two groups, one containing copper and silver transporters and the other containing transporters of the divalent metal cations (Rensing et al., 1999). These proteins comprise eight transmembrane helices, that presumably form the ionic pathway across the membrane, and couple metal transport to the hydrolysis of ATP at a large cytoplasmic loop (c. 400 amino acids) located between transmembrane helices 6 and 7. Other features common to these proteins include a proline residue flanked by probable metal-binding residues (CPX motif) within the sixth transmembrane helix and a soluble aminoterminus typically comprising one or more metal-binding domains (one or two in bacteria). These amino-terminal domains possess typical babbab ferredoxin-like folding (Banci et al., 2002a) and bear the motif GXXCXXC associated with metal-binding and the formation of copperbridged hetero-dimeric species during copper transfer with copperchaperones (Arnesano et al., 2001; Banci et al., 2003; Gitschier et al., 1998; Pufahl et al., 1997). The amino-terminal metal-binding domains are not necessary for metal ion transport but may interact with the intracellular ATP-binding loop of the transporter to modulate activity (Bal et al., 2001; Mitra and Sharma, 2001; Tsivkovskii et al., 2001; Voskoboinik et al., 2001). There is a high degree of specificity with respect to the metal ions transported by the different P1B-type ATPases. The metal-binding sites within the membrane-transport sites and the amino-terminal domains
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both appear to contribute to metal-specificity (Banci et al., 2002b, 2006b; Borrelly et al., 2004; Finney and O’Halloran, 2003; Hou et al., 2001; Mandal et al., 2004). Furthermore, studies with a zinc-transporter, AztA, have revealed that possession of two amino-terminal metal-binding domains, as opposed to just one, may provide a further level of metaldiscrimination (Liu et al., 2007). In this case, export of cadmium is prevented due to the thiophilic nature of cadmium causing it to recruit cysteines from both metal-binding domains and forming nonproductive bridged complexes, while the ‘‘correct’’ metal, zinc, binds to a pair of cysteines in one or other domain, but not both, and thereby migrates along an affinity gradient toward the membrane for transport. Restricted contact of the amino-terminal domains of the P1B-type ATPases with copper-chaperones (refer to Section II.E) may also contribute toward metal-specificity (Borrelly et al., 2004). Although bacterial coppertransporting P1B-type ATPases are known that have roles in import and export to/from the bacterial cytosol, this cannot be predicted based upon sequence analysis.
B. Copper acquisition No specific copper import system has been identified in E. coli, possibly reflecting no cytosolic requirement for copper, and the mechanism of copper entry into E. coli is largely unknown. Copper has been suggested to cross the outer membrane through porins, since porin-deficient mutants have been obtained when selecting for copper-resistance (Lutkenhaus, 1977). However, no increase in metal-tolerance has since been reported for isogenic OmpF and/or OmpC mutants (Li et al., 1997). Within the periplasm, the respiratory chain Ndh-2 has specific cupricreductase activity (Rapisarda et al., 1999), which possibly contributes to Cu(I) uptake by passive diffusion or by yet unidentified copper-importers and/or nonspecific uptake systems for other metals such as sodium or potassium. In contrast to E. coli, specific copper-importers have been described in other bacteria including Synechocystis PCC 6803, E. hirae, and Listeria monocytogenes DRDC8 (Francis and Thomas, 1997b; Tottey et al., 2001; Wunderli-Ye and Solioz, 2001), despite the latter two having no known cytosolic copper-requirement.
1. P1B-type ATPases: E. hirae CopA and Synechocystis PCC 6803 CtaA
Current evidence that E. hirae CopA is involved in copper-import remains indirect. E. hirae mutants lacking copA show no change in copper-resistance but, unlike wild-type cells, fail to grow after two to three generations in metal-limited media (treated with the chelator 8-hydroxyquinoline). In addition, the copA mutants are more resistant to silver than wild-type cells, which is presumed to result from reduced fortuitous silver uptake by
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CopA and subsequent adventitious binding (Odermatt et al., 1993). Purified CopA can catalyze ATP hydrolysis and form an acylphosphate intermediate, which is inhibited by vanadate (typical of P-type ATPases). Inhibition has also been detected in the presence of Cu(I) chelators, but not chelators of divalent cations, further supporting a role in Cu(I)-transport (Wunderli-Ye and Solioz, 2001). CopA possesses a single amino-terminal metal-binding domain, which interacts with the CopZ copper-chaperone (Multhaup et al., 2001). CopZ is suggested to channel copper supplied by CopA to both the CopY repressor and CopB for export (Fig. 8.1). Deletion of the ctaA gene in the cyanobacterium Synechocystis PCC 6803 caused no change in copper-tolerance but reduced the amount of copper accumulated per cell (Tottey et al., 2001), while deletion of the related gene from Synechococcus PCC 7942 caused (slightly) elevated copper-resistance, which was attributed to reduced copper-import at the cytoplasmic membrane (Phung et al., 1994). Consistent with a role for CtaA in copper-import, Synechocystis PCC 6803 mutants lacking ctaA have low cytochrome caa3 oxidase activity in purified membranes and are impaired in photosynthetic electron transport via plastocyanin (Tottey et al., 2001). In the model (Fig. 8.1), the copper-chaperone Atx1 interacts with the single amino-terminal metal-binding domain of CtaA, where it is presumed to acquire copper, and donates it to PacS for transport into the thylakoid (Banci et al., 2006a; Tottey et al., 2001, 2002). Mutants deficient in atx1 and pacS also show reduced cytochrome caa3 oxidase activity and plastocyanin mediated electron transport (Tottey et al., 2001, 2002).
2. FutA2 A periplasmic iron-binding protein, FutA2, has also been shown to contribute to copper-import in Synechocystis PCC 6803. Mutants lacking futA2 have low cytochrome caa3 oxidase activity and accumulate cytochrome c6 for electron transport whilst copper-accumulation in plastocyanin is impaired (Waldron et al., 2007). Furthermore, the total amount of copper in the major soluble protein and small-molecule complexes from whole cell extracts is less in futA2 mutants, compared to wild-type cells, while additional copper accumulates in periplasmic soluble protein and smallmolecule complexes. It is proposed that FutA2 contributes towards the inward supply of copper from the periplasm by sequestering Fe(III) and thereby limiting Fe(III) associations with vital binding sites for other metals, such as the copper-binding sites of CtaA (Waldron et al., 2007).
3. Methanobactin
Some methane-oxidizing bacteria, such as Methylosinus trichosporium OB3b and Methylococcus casulatus (Bath), are known to secrete a small siderophore-like compound called methanobactin (C45N12O14H62Cu, 1216 Da) which is suggested to have a role in copper-uptake and/or
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copper-detoxification (DiSpirito et al., 1998; Kim et al., 2004, 2005; Tellez et al., 1998). Methanobactin binds both Cu(I) and Cu(II) and may itself reduce Cu(II) to Cu(I) (Choi et al., 2006; Hakemian et al., 2005). It has been postulated that the active site of pMMO (refer to Section 1.B) includes methanobactin or alternatively methanobactin scavenges copper from the environment and supplies pMMO in the periplasm and/or periplasmic invaginations (Kim et al., 2004, 2005).
C. Copper detoxification The use of copper-transporting P1B-type ATPases for the rapid export of available copper ions from the cytosol is a common theme amongst bacterial copper-resistance mechanisms and there are numerous examples of these proteins conferring copper-tolerance throughout the literature. In Synechocysis PCC 6803, the export of copper by PacS not only provides copper-resistance but also has a role in supplying copper to proteins within the thylakoid (Tottey et al., 2001, 2005). Similarly eukaryotic cells use copper-specific P1B-type ATPases to remove copper from the cytosol into the trans-Golgi, where it is incorporated into proteins (Yuan et al., 1995). Some bacteria, including Synechocystis PCC 6803, E. hirae, and B. subtilis (not E. coli), in common with eukaryotic cells, also possess copper-chaperones (e.g., CopZ and Atx1, Fig. 8.1), which may contribute to copper-trafficking by channeling copper to these proteins for export. If copper concentrations overwhelm these proteins, some bacteria invoke additional mechanisms that confer additional copper-resistance. The responses of E. coli to elevated copper levels have been studied in detail and primarily involve the chromosomally-encoded cue and cus systems. The cus system only confers copper-tolerance under extreme copper stress while the cue system is the primary copper homeostasis system (Outten et al., 2001). As extracellular copper levels increase, CueR mediates production of a copper-exporting P1B-type ATPase CopA at the cytoplasmic membrane and a periplasmic multicopper oxidase CueO, these three proteins constituting the cue system. Although these proteins apparently clear the cytosol of excess copper, this is retained within the periplasm and thus may serve as a compartmentalized store (Outten et al., 2001). If copper levels continue to increase, expression of the cusCBFA operon is induced by the CusR/S two-component sensory system, which detects surplus Cu(I) in the periplasm, mediating export of copper across the outer membrane. The cus system is particularly important in providing copper-tolerance under anaerobic conditions (Outten et al., 2001). Some E. coli strains also harbor the plasmid-borne pco system which involves seven genes, pcoABCDRSE, providing yet further copper-resistance. The mechanism of copper detoxification provided by this system is largely unknown but includes the multi-copper oxidase
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PcoA and its putative partner PcoC, both of which are exported to the periplasm (Lee et al., 2002), PcoD is thought to transport copper across the cytoplasmic membrane, PcoB is a predicted outer membrane protein and PcoE is a periplasmic protein that binds copper (Rensing and Grass, 2003). PcoRS form a two-component regulator required for copper-inducible expression of the pco genes. A number of other proteins have also been linked to copper-resistance in E. coli (Kershaw et al., 2005; Yamamoto and Ishihama, 2005), including the products of the cutABCDEF genes, which were identified based on the preliminary characterization of copper-sensitive mutants (Rouch et al., 1989). However, few of these genes have been directly linked to copper metabolism, transport, or regulation (Crooke and Cole, 1995; Fong et al., 1995; Gupta et al., 1997) and hence are not described here.
1. The E. coli cue system a. CueR Expression of both cueO and copA is substantially induced in response to elevated copper levels by the action of the CueR transcriptional regulator which has zeptamolar sensitivity to free Cu(I), less than one atom per cell (Changela et al., 2003; Outten et al., 2000; Stoyanov et al., 2001). CueR belongs to the MerR-family of metal-responsive transcriptional regulators (reviewed by Brown et al., 2003), other members of which include zincsensing ZntR (Brocklehurst et al., 1999; Outten and O’Halloran, 2001), mercury-sensing MerR, cadmium-sensing CadR (Brocklehurst et al., 2003), lead-sensing PbrR (Borremans et al., 2001), and cobalt-sensing CoaR (Rutherford et al., 1999). These proteins bind to the promoters of their target genes in the presence and absence of their effector metals (Stoyanov et al., 2001). In the presence of elevated metal ions, they allosterically activate transcription initiation by RNA polymerase by realigning abnormally spaced consensus RNA polymerase recognition sequences, while in the absence of metal ions these proteins may cause slight (c. twofold) repression (Ansari et al., 1992; Outten et al., 1999; Parkhill et al., 1993). The operator-promoter regions upstream of copA and cueO reveal unusual spacing (19-bp, rather than 17-bp) between 10 and 35 RNA polymerase consensus binding sequences, characteristic of genes regulated by MerR-family transcriptional activators (Stoyanov et al., 2001). Mutants lacking cueR show reduced copper-tolerance and lack copperinduced expression of copA and cueO (Outten et al., 2000; Stoyanov et al., 2001). In addition to Cu(I), CueR is responsive to both Ag(I) and Au(I) ions in vivo and in vitro (Changela et al., 2003; Stoyanov and Brown, 2003; Stoyanov et al., 2001), although the biological relevance of this is not clear and induction may simply result from Ag(I) and Au(I) mimicking Cu(I) in the CueR metal-binding site. The crystal structure of a CueR homodimer reveals a buried metal-receptor site at the dimer interface that contributes to selectivity toward the monovalent metals by restricting binding to a linear two-coordinate geometry involving two cysteines, Cys112 and
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Cys120 (Changela et al., 2003). Disruption of these cysteines causes loss of copper, silver, and gold sensing in vivo and in vitro (Chen et al., 2003; Stoyanov and Brown, 2003). In addition to copper-responsive regulation by CueR, copA has been suggested to be under the control of other transcriptional regulators including CpxR that responds to cell envelope stress (Outten et al., 2000).
b. Multi-copper oxidase CueO Multi-copper oxidases catalyze the oxidation of a variety of substrates, such as polyphenols, aromatic polyamines, Lascorbate and metal ions, and transfer the liberated electrons to a copper cluster causing the concomitant four-electron reduction of dioxygen to water (Sakurai and Kataoka, 2007). These proteins require dioxygen for activity and hence are inactive under anaerobic conditions. Prominent members of this protein family are the fungal laccases, which are implicated in a variety of processes including lignin degradation and biosynthesis, pigmentation, sporulation, and pathogenesis (Sakurai and Kataoka, 2007). As a multi-copper oxidase, E. coli CueO is proposed to contribute to copperdetoxification by converting Cu(I) to less toxic Cu(II) in the periplasm (Outten et al., 2001), although its precise role remains to be established. CueO is known to bind four copper ions and is exported to the periplasm via the TAT pathway (for prefolded proteins) where it exhibits copper-inducible oxidase activity (Grass and Rensing, 2001; Outten et al., 2001; Roberts et al., 2002; Singh et al., 2004). The molecular chaperone DnaK is essential for TAT targeting of CueO, and is required after protein-folding (Graubner et al., 2007). However, it is not known whether CueO acquires copper in the periplasm or is exported pre-metallated and thereby contributes to copper-export from the cytosol. Mutants lacking cueO show a slight reduction in copper-tolerance under aerobic conditions, but not in the absence of dioxygen, and CueO can protect periplasmic enzymes from copper-induced damage (Grass and Rensing, 2001; Outten et al., 2001). In addition to Cu(I), CueO can oxidize a variety of other compounds in the presence of copper, including the catechol iron siderophore enterobactin (Grass et al., 2004; Kim et al., 2001). By oxidizing enterobactin, CueO may protect E. coli from copper-toxicity by preventing enterobactin mediated reduction of Cu(II) to Cu(I). Substrate specificity of CueO appears to result from a methionine-rich helix which obstructs the substrate-binding site in the absence of elevated Cu(I) (Kataoka et al., 2007; Li et al., 2007). In addition to CueO, some E. coli strains possess a second multi-copper oxidase PcoA as part of the plasmid-encoded pco copper-resistance system (Brown et al., 1992). CueO-related proteins have also been associated with copper-resistance in a number of other bacteria and include CopA from Pseudomonas syringae pathovar tomato associated with the plasmid encoded cop copper-resistance operon (Cha and Cooksey, 1993), CutO from the photosynthetic purple bacterium Rhodobacter capsulatus
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(Wiethaus et al., 2006), and CuiD from Salmonella typhimurium which provides resistance to hydrogen peroxide in addition to copper (Lim et al., 2002). Unlike E. coli CueO, the multi-copper oxidases from R. capsulatus and S. typhimurium are reported to somehow provide copper-tolerance under both aerobic and anaerobic conditions (Espariz et al., 2007; Wiethaus et al., 2006).
c. P1B-type ATPase CopA E. coli CopA has a role in copper-export under both aerobic and anaerobic conditions (Outten et al., 2001). Mutants lacking copA are hypersensitive to copper in the presence or absence of oxygen (Outten et al., 2001; Rensing et al., 2000), while tolerance to other metals (silver, cadmium, zinc, and lead) is unaffected, at least under aerobic conditions (Rensing et al., 2000). Furthermore, these mutants show decreased copper efflux and accumulate copper (Petersen and Mller, 2000), while everted-vesicles from cells expressing copA show ATP-coupled accumulation of copper in the presence of the reductant dithiothreitol (Rensing et al., 2000). CopA can catalyze ATP hydrolysis to form an acylphosphate intermediate (inhibited by vanadate) in the presence of Cu(I) or Ag(I), but not Zn(II), Cu(II) or Co(II) (Fan and Rosen, 2002), and the use of a luminescent biosensor under the control of the copA promoter also indicates a role for CopA in regulating silver levels, in addition to copper, but not gold (Stoyanov et al., 2003). CopA possesses two amino-terminal metal-binding domains, neither of which are required for formation of the acylphosphate intermediate or copper-resistance and transport (Fan and Rosen, 2002; Fan et al., 2001). It is tempting to speculate that the possession of two such domains contributes to the metal-selectivity of this transporter, for example by forming nonproductive complexes (Liu et al., 2007) with highly thiophilic metals such as gold. Interestingly, S. typhimurium possesses two P1B-type ATPases, CopA and GolT (Fig. 8.2), both of which contribute to copper-resistance (Espariz et al., 2007). However, CopA (the E. coli CopA orthologue) appears to be the principal copper-exporter and provides only slight resistance to gold, whereas GolT with a single amino-terminal metal-binding domain is primarily associated with gold-resistance (Checa et al., 2007; Espariz et al., 2007) (refer to Section II.D.1). The Cu(I)-exporting P1B-type ATPases CopA from B. subtilis possesses two amino-terminal metal-binding domains (Banci et al., 2002a) whereas a single domain is found in PacS from Synechocystis PCC 6803 (Tottey et al., 2001). CopB from E. hirae lacks an amino-terminal GXXCXXC metal-binding motif although a histidine rich region is present which likely constitutes a metal-binding site (Solioz and Stoyanov, 2003).
2. The E. coli cus system
While the cue system confers copper-tolerance under moderate to high copper levels, the cus system is only required under conditions of extreme copper stress and is particularly important in anaerobic environments
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FIGURE 8.2 S. typhimurium possesses two MerR-type copper-responsive regulators CueR and GolS. (A) In response to elevated copper levels, CueR triggers expression of a copper-exporting P1B-type ATPase CopA and a multicopper oxidase CuiD associated with copper-resistance, while GolS triggers expression of a second P1B-type ATPase GolT and a CopZ/Atx1-like protein GolB. GolS, GolT, and GolB have primarily been associated with gold-sensing and -resistance (Checa et al., 2007; Espariz et al., 2007). (B) An alignment of the operator-promoter regions of the target genes of CueR (PcopA and PcuiD) and GolS (PgolTS and PgolB) showing a consensus motif (below) containing a region of dyad symmetry (arrows) and RNA polymerase consensus 10 and 35 binding sequences (bold and underlined). The 10 and 35 sequences are separated by a long (19-bp) spacer region typical of promoters under the control of MerR-family transcriptional activators. It remains to be tested whether or not there is an overlap in the target promoters of the two sensors.
(Outten et al., 2001). The cusCFBA structural genes are induced in response to highly elevated copper levels by the CusRS two-component sensory system which typically monitors stress at the cell envelope and is thought to respond to Cu(I). No expression of cusCFBA is detected in mutants lacking cusR (Outten et al., 2001). In the presence of oxygen, Outten and co-workers (2001) have shown that while half maximal expression from the cueO and copA promoters occurs at c. 10 mM copper, half maximal expression from the cusCFBA promoter occurs at much
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higher levels of copper (200 mM), suggesting that the cus system is only activated once the cue system is overwhelmed. In contrast, under anaerobic conditions half maximal expression from the cusCFBA promoter occurs at lower copper levels (70 mM) than observed aerobically yet the level of copper required for half maximal induction of cueO is increased (60 mM) implying a greater role for cus under anaerobic conditions and possibly relating to a shift in the periplasmic copper ratio to the Cu(I) state. Furthermore, mutants lacking cusR or cusA have normal coppertolerance under aerobic conditions (Franke et al., 2001; Outten et al., 2001) but copper-sensitivity and increased copper accumulation is detected for the cusR mutant under anaerobic conditions, consistent with disruption of anaerobic copper-export (Outten et al., 2001). However, in the presence of oxygen, cueR/cusR double mutants do show a substantial reduction in copper-tolerance, compared to either single mutant or wild-type cells, and deletion of any of the four cusCFBA structural genes in conjunction with cueO also causes loss of copper-tolerance (Franke et al., 2003; Grass and Rensing, 2001). Hence, the cus system can play a role in aerobic conditions when the cue system cannot be induced or is impaired. A role for the cus system in providing silver-resistance has also been shown (Franke et al., 2001). The products of the cusC, cusB, and cusA genes are thought to form a multiunit transport complex that spans both membranes and the periplasmic space (Outten et al., 2001). CusC is an outermembrane protein with homology to the TolC stress-response protein (Koronakis et al., 2000), CusB belongs to the membrane fusion protein family which are anchored into the cytoplasmic membrane with a long periplasmic-spanning domain (Zgurskaya and Nikaido, 1999), and CusA is a member of the RND family of proton antiporters associated with the export of a range of substrates including metal ions (Saier et al., 1994). Clusters of methionines within the deduced periplasmic domains of CusA and CusB have been shown to be required for copper-resistance and, in the case of CusB, Cu(I)-binding (Bagai et al., 2007; Franke et al., 2003). The CusCBA complex is proposed to transport Cu(I) from the cytosol across the cell envelope into the extracellular milieu. CusF is a small (10 kDa) periplasmic protein which binds a single Cu(I) (or Ag(I)) ion and interacts with both CusC and CusB (Franke et al., 2003). The recent elucidation of the structure of the Cu(I) bound form of CusF has revealed a new metal-binding site in which Cu(I) is tetragonally displaced from a Met2His ligand plane toward a tryptophan which involves cation-p interactions (Xue et al., 2008). The tryptophan in CusF appears to block access to its bound Cu(I), while the weaker cation-p interactions versus a coordinate covalent bond have implications for metal transfer, for example with the methionine clusters of CusB and/or CusA. This novel site in CusF has therefore been proposed to meet the
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demands of controlling metal exchange whilst preventing adventitious redox reactions (Xue et al., 2008).
D. Sensors of elevated copper levels Copper-responsive transcriptional regulators detect surplus copper-ions and modulate transcription of genes with roles in copper-uptake, -channeling, -efflux, or -detoxification. In E. coli, CueR is the intracellular Cu(I) sensor that activates expression of CopA and CueO, while the two component CusRS system senses periplasmic Cu(I) and triggers expression of CusCFBA. In addition, some strains possess a second two component Cu(I) sensor, PcoRS, as part of the plasmid-borne pco resistance determinant. Bacteria that lack CueR homologues may use other, structurally distinct, intracellular copper sensors that functionally substitute for CueR, such as CopY in E. hirae and CsoR in Mycobacterium tuberculosis and B. subtilis (Fig. 8.1).
1. MerR-family copper-sensors CueR belongs to the MerR-family of transcriptional activators (refer to Section II.C.1a). Other bacteria that possess copper-tolerance systems under the control of CueR-like proteins include Pseudomonas putida (Adaikkalam and Swarup, 2002), Rhizobium leguminosarum (Reeve et al., 2002), and S. typhimurium (Checa et al., 2007; Espariz et al., 2007; Kim et al., 2002). In the case of S. typhimurium, two CueR-like proteins are present (Fig. 8.2), one designated SctR (Kim et al., 2002) or CueR (Espariz et al., 2007) and the second designated GolS (Checa et al., 2007). The former is an orthologue of E.coli CueR (91% identity) and has been shown to mediate copper-responsive expression of the multi-copper oxidase CuiD and P1Btype ATPase CopA, conferring copper-resistance (Espariz et al., 2007; Kim et al., 2002; Lim et al., 2002). GolS on the other hand, regulates expression of a second P1B-type ATPase GolT, a CopZ/Atx1-like copper-chaperone GolB, and a CBA family drug-efflux system GesABC, and is primarily associated with gold-resistance (Checa et al., 2007; Pontel et al., 2007). Elevated expression of GolT, GolS, and GolB occurs in response to copper and gold, while expression of GesABC is only induced by gold (Pontel et al., 2007). However, a role for GolS in gold-resistance is somewhat unexpected from a biological point of view and the physical chemistry of Au(I) ions would be consistent with them mimicking Cu(I) in the metalbinding sites of these proteins as has been suggested for E. coli CueR (Changela et al., 2003; Stoyanov and Brown, 2003). Hence, it remains possible that both S. typhimurium CueR and GolS have evolved to sense Cu(I) under different surplus copper conditions and by causing differential expression of the cue and gol systems may allow subtle adaptation to excess of these metal ions in the cytosol.
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2. CopY-family copper sensors
The copYZAB operon in E. hirae is regulated by the copper-responsive repressor CopY (Odermatt and Solioz, 1995). The current model (Portmann et al., 2004) indicates that at low copper concentrations CopY is present as a Zn(II) containing homodimer and binds to the copYZAB operator-promoter region repressing transcription (Cobine et al., 1999). In the presence of copper, the copper-chaperone donates Cu(I) to CopY, displacing Zn(II), alleviating DNA-binding and allowing transcription of copYZAB to proceed. The carboxyl-terminal region of CopY possesses a CXCXXXXCXC metal-binding motif. Each Zn(II) ion is coordinated to all four cysteines in the repressing form of CopY, and is replaced by two Cu(I) ions in the induced, non DNA-binding form (Cobine et al., 2002). CopY-like regulatory proteins are not widely distributed amongst bacteria but have been associated with the copper-resistance determinants of Enterococcus faecium (Hasman et al., 2006), Lactococcus lactis IL1403 (Magnani et al., 2008), Streptococcus mutans (Vats and Lee, 2001), and Streptococcus gordonii (Mitrakul et al., 2004). The amino-terminal half of CopY has structural similarity to the BlaI and MecI repressors that belong to the ‘‘winged helix’’ family of proteins and mediate resistance to b-lactam antibiotics (Portmann et al., 2006). Consistent with this, CopY, BlaI, and MecI bind to similar sequences within the promoters of their target genes with the consensus binding motif TACAXXTGTA (Portmann et al., 2006).
3. CsoR-family copper sensors
The recently described intracellular copper sensor CsoR from M. tuberculosis is the founding member of what appears to be a large family of bacterial Cu(I)-responsive repressors (Liu et al., 2007). M. tuberculosis csoR is part of the cso operon which also contains a small open reading frame Rv0968 of unknown function and ctpV encoding a P1B-type ATPase with sequence features of a Cu(I)-transporter. Expression of the cso operon is induced by elevated copper levels and to a lesser extent silver, but not other metals (lead, zinc, cadmium, nickel, or cobalt), consistent with a role in copper-export (Liu et al., 2007; Ward et al., 2008). CsoR binds to a region of the cso operon containing dyad symmetry and DNAbinding is weakened upon Cu(I)-binding, thus alleviating repression in elevated metal (Liu et al., 2007). The structure of Cu(I)-CsoR reveals a homodimer with two Cu(I) ions, each Cu(I) bound in a triganol coordination complex involving two cysteines and a histidine in a subunit bridging site (Liu et al., 2007). CsoR-related sequences are widely distributed in bacterial genomes and a second Cu(I)-sensing CsoR has recently been characterized from B. subtilis which mediates copper-responsive expression of copZ and copA (Smaldone and Helmann, 2007). The majority of identified CsoR-related
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sequences appear to possess all three Cu(I)-binding ligands, consistent with Cu(I)-sensing (Liu et al., 2007). However, some of the more distantly related sequences lack all three ligands raising the intriguing possibility that they are involved in sensing metals other than Cu(I) or other substrates such as organic molecules.
E. Copper-chaperones In eukaryotes, highly conserved proteins are used for copper-import, copper-channeling, or for ejecting copper from the cell. These include copper-chaperones that direct copper to its three destinations: copper, zinc superoxide dismutase; mitochondrial cytochrome c oxidase; and the trans-Golgi apparatus for incorporation into proteins (O’Halloran and Culotta, 2000). Specific interactions and metal exchange between the copper-chaperones and their targets allow proteins to acquire their copper cofactor under physiologically low metal conditions in vivo (Carroll et al., 2004). The trafficking of copper into the trans-Golgi involves the copperchaperone, Atx1 in yeast or Atox1 (Hah1) in humans, interacting with, and donating copper to, a copper-specific P1B-type ATPase for transport across the membrane (reviewed in O’Halloran and Culotta, 2000; Singleton and Le Brun, 2007). Similarly, the copper-chaperone CCS is the primary source of copper for yeast and mammalian copper, zinc superoxide dismutase (Sod1) (Culotta et al., 1997; Rae et al., 2001; Wong et al., 2000). CCS physically interacts with Sod1 to insert a copper ion into the active site (Culotta et al., 1997; Gamonet and Lauquin, 1998; Schmidt et al., 2000; Torres et al., 2001), but also has a role in catalyzing the oxidation of a conserved disulphide that is essential for Sod1 function (Furukawa et al., 2004). Only a few mammalian cell types are able to support a low level of copper incorporation into Sod1 in the absence of their copper-chaperone (Culotta et al., 1997; Wong et al., 2000) consistent with the assertion that most cells lack freely available copper and a pool of free copper ions is not used in physiological activation of metalloenzymes (Rae et al., 2001). E. coli lacks sequences with similarity to known copper-chaperones. However, some bacteria possess Atx1 homologues, for example Atx1 from Synechocystis PCC 6803 (Tottey et al., 2002), CopZ from B. subtilis (Banci et al., 2001; Radford et al., 2003), CopZ from E. hirae (Magnani and Solioz, 2005), and GolB from S. typhimurium (Checa et al., 2007). Like their eukaryotic counterparts, the bacterial Atx1 and CopZ proteins are suggested to play a role in preventing adventitious Cu(I)binding and contribute to cytosolic Cu(I)-export.
1. Bacterial copper-chaperones: CopZ/Atx1 The cyanobacterial Atx1 acts with two P1B-type ATPases, CtaA and PacS at the cytoplasmic and thylakoid membranes, respectively, to traffic copper to the thylakoid for cytochrome caa3 oxidase activity and
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photosynthetic electron transport via plastocyanin (Tottey et al., 2002). B. subtilis CopZ acts with copper-exporting CopA (Banci et al., 2003; Radford et al., 2003). E. hirae CopZ interacts and exchanges copper with the CopA transporter, which appears to import copper (Multhaup et al., 2001), and may also interact with copper-exporting CopB (Solioz and Stoyanov, 2003). A role for E. hirae CopZ in routing copper to the cytoplasmic copper sensor CopY, to alleviate CopY-mediated repression of the copYZAB operon, has also been demonstrated (Cobine et al., 1999) (Fig. 8.1). Differential protease-mediated degradation of apo-CopZ and Cu(I)-CopZ in E. hirae is also suggested to contribute to regulation (Magnani and Solioz, 2005). The Atx1/CopZ proteins adopt a very similar structure to the aminoterminal metal-binding domains of the P1B-type ATPases with typical babbab ferredoxin-like folding and a GXXCXXC metal-binding motif present on a flexible solvent-exposed loop (Arnesano et al., 2001; Banci et al., 2003, 2004; Rosenzweig et al., 1999). Cu(I)-bridging between the cysteines of donor and acceptor proteins mediates protein–protein interactions and transfer, with complementary charged surfaces also contributing to these interactions (Banci et al., 2006b). The formation of tricoordinate Cu(I)-bridged intermediates is presumed to be a general feature in the Cu(I) transfer mechanism and has been reviewed extensively elsewhere (Huffman and O’Halloran, 2001; Singleton and Le Brun, 2007; Tottey et al., 2005).
2. B. subtilis Sco1
Cytochrome caa3 oxidase activity in yeast and mammals requires the action of Sco proteins, in addition to the mitochondrial copper-chaperone Cox17, to assemble the di-copper A site at the inner mitochondrial membrane (Banci et al., 2007). B. subtilis possesses a single Sco homologue (BsSco or YpmQ), which is required for the activity of cytochrome caa3 oxidase but not of the aa3-type (quinol) oxidase, with only a copper B site, consistent with a similar role to its mitochondrial counterparts (Balatri et al., 2003; Mattatall et al., 2000). Genes encoding Sco proteins have also been identified in the genomes of a number of other bacteria, some of which lack a cytochrome oxidase with a di-copper A site, and a more general role for Sco proteins as copper-chaperones for other metalloenzymes has been suggested (Banci et al., 2007).
III. COPPER AND BACTERIAL PATHOGENICITY During infection of a host, bacterial pathogens must sense and respond rapidly to a wide variety of fluctuating conditions, such as changes in the availability of metal ions and exposure to reactive oxygen species. Indeed, copper homeostatic mechanisms are increasingly being linked to bacterial
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pathogenicity, but the nature of their role in virulence is largely unknown and is anticipated to vary depending on the site of infection and the adaptive strategies used by different bacteria. Changes in copper levels have been detected in the livers and spleens of animals infected with a range of pathogens, including viruses, bacteria, and trypanosomes (Crocker et al., 1992; Ilba¨ck et al., 2003; Matousek de Abel de la Cruz et al., 1993; Tufft et al., 1988). These changes have been reported to be up, down, or even biphasic during the course of infection. Within the gastrointestinal tract and gall bladder, the concentration of copper may be high due, at least in part, to the action of the Wilson P1B-type ATPase (ATP7B) which transports copper from the liver into bile for excretion (Lutsenko et al., 2007). Furthermore, the toxicity of copper is likely to be increased due to the acidic anaerobic conditions. Thus, within the gastrointestinal tract, bacterial pathogens likely have a requirement for copper-resistance. Pathogen killing within professional phagocytes involves the oneelectron reduction of oxygen by the respiratory burst (NADPH) oxidase generating superoxide (Fig. 8.3). This is highlighted by the rare syndrome of chronic granulomatous disease (X-CGD) in which loss of respiratory burst oxidase function results in an inability of patients to combat microbial infections. For some bacterial pathogens, such as S. typhimurium, protection from the products of the respiratory burst oxidase is dependent upon the function of extracytoplasmic copper and zinc superoxide dismutases (SodC proteins) (Battistoni, 2003). These enzymes catalyze the dismutation of superoxide into oxygen and hydrogen peroxide by the alternate reduction and oxidation of a copper ion that constitutes the active site. Highly virulent S. typhimurium strains possess multiple sodC genes (Battistoni, 2003). These genes are dispensable for growth under normal laboratory conditions but are crucial for bacterial–host interactions (Ammendola et al., 2005; Battistoni et al., 2004; De Groote et al., 1997; Fang et al., 1999; Farrant et al., 1997; Sansone et al., 2002; Uzzau et al., 2002). The ability of these proteins to acquire copper within the periplasm is therefore crucial for virulence. However, within the phagosome it is likely that bacterial pathogens must also avoid copper-mediated toxicity. Indeed, the toxic potential of copper is now thought to constitute a crucial component of the respiratory burst killing mechanism (Fig. 8.3) and an increase in copper levels is detected in phagosomes isolated from macrophages infected with S. typhimurium (unpublished). Consistent with these findings, the ability of phagocytes to kill ingested bacteria is reduced in copper deficiency (Percival, 1998), and copper deficient animals are highly vulnerable to bacterial infection while protection is restored by copper supplementation (Suttle and Jones, 1989). The contribution of bacterial copper trafficking proteins, such as S. typhimurium CopA, GolT, and GolB, in avoiding copper mediated toxicity in the phagosome and supplying copper to the periplasmic SodC proteins remains to be established.
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FIGURE 8.3 The toxic potential of copper may be exploited by phagocytes as a crucial component of the oxidative burst. Copper enters the cell through the high-affinity copper transporter Ctr1 and binds to cytosolic copper-chaperones. Atox1 shuttles Cu(I) to the Cu(I) transporting P1B-type ATPase ATP7A at the trans-Golgi network (TGN) where it supplies Cu(I) for maturing secreted copper proteins. In elevated copper levels, ATP7A may be relocated to both perinuclear vesicles and the phagosome (Leary and Winge, 2007). Within the phagosome, Cu(I) may contribute to the bacteriocidal action of the respiratory burst oxidase (triangle) by catalyzing Fenton chemistry causing the production of highly toxic hydroxyl radicals (OH). The antimicrobial activity of the respiratory burst may also be increased when combined with the activity of nitric oxide (NO) synthase (also present in phagocytes) forming highly toxic peroxynitrite (ONOO). By catalysing the dismutation of superoxide (O2) into oxygen and hydrogen peroxide (H2O2), copper-requiring bacterial SodC proteins have a role in providing resistance to reactive oxygen and nitrogen species, although in the presence of Cu(I) this may contribute to Fenton chemistry.
Consistent with the requirement for different bacterial pathogens to adapt to changing copper levels during infection, genes encoding copperexporting P1B-type ATPases have been identified amongst the major genes expressed during infection of lungs and/or macrophages by the intracellular pathogens M. tuberculosis and S. typhimurium (Graham and Clark-Curtiss, 1999; Heithoff et al., 1997; Talaat et al., 2004), and by in vivo expression technology (IVET) using Staphylococcus aureus in the murine renal abscess model (Lowe et al., 1998). Furthermore, disruption of the gene for a copper-exporting P1B-type ATPase has been shown to reduce the pathogenicity of Pseudomonas aeruginosa in mice (Schwan et al., 2005) while mutants of L. monocytogenes DRDC8 lacking a P1B-type ATPase,
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CtpA, thought to import copper, were cleared much more rapidly from the livers of infected mice than the wild type strain (Francis and Thomas, 1997a). Hence, copper homeostasis and adaptation to different copper stresses is clearly important for bacterial pathogens surviving and growing in different host tissues.
IV. COPPER AS A BIOCIDE The cytotoxic properties of copper have been exploited by man since ancient civilizations. Its use as a biocide is recorded as far back as c. 2400 BC in an ancient Egyptian medical text (Smith Papyrus) which describes copper as a sterilizing agent for drinking water and wounds. More recent exploitation of copper cytotoxicity includes the protection of ship’s hulls by copper sheathing or by antifouling paints containing copper (subsequently replaced by tin compounds), its use in algicides and wood preservatives, and incorporation of copper into fabrics used for clothing and bedding to prevent microbial growth. Copper is also commonly used as a disinfectant for veterinary purposes and in the food industry. Copper is added to animal feed to inhibit bacterial populations in the intestinal tract and for disinfecting the claws of cattle (Aarestrup and Hasman, 2004), as well as promoting growth in both industrial and organic pig production (Edmonds et al., 1985; Hasman et al., 2006). In addition, the toxic effects of copper are used in agriculture to control bacterial and fungal diseases on a variety of crops (Aarestrup and Hasman, 2004). The emergence of nanoscience and nanotechnology in the last decade has also provided the basis for examining the bacteriocidal effects of copper nanoparticles with promising results (Cioffi et al., 2005; Ruparelia et al., 2007; Yoon et al., 2007). These nanoparticles can be immobilized and coated onto surfaces and used in a range of applications such as medical devices, water treatment, and food processing. Furthermore, there is considerable new interest in the use of copper alloys as a way of controlling drugresistant bacterial infections such as methicillin-resistant S. aureus (MRSA). A recent study (Noyce et al., 2006) demonstrated that strains of MRSA were completely killed within 90 min on pure copper surfaces whereas they can live for up to three days on stainless steel, thereby providing the rationale for replacing stainless steel door handles and taps with copper ones in hospitals (http://www2.uhb.nhs.uk). Clearly, a concern is that the widespread use of copper as a biocide will select for copper-resistant strains of bacteria. Indeed, some bacterial pathogens are known to have acquired plasmid-borne copper-resistance mechanisms (Brown et al., 1992), in addition to the chromosomal copper homeostatic mechanisms described above. Well documented examples are an E. coli strain found in the feces of copper-fed pigs and P. syringae
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pathovar tomato isolated from copper exposed plants where copperresistance was attributed to the plasmid encoded pco and cop operons, respectively, which encode related proteins involved in periplasmic copper handling (Brown et al., 1995; Cooksey, 1994; Lee et al., 2002; Rensing and Grass, 2003) (refer to Section II.C). Of particular concern is the finding that selection of copper-resistance may result in co-selection of antibioticresistance determinants (Hasman et al., 2006). Hence, a high degree of caution needs to be applied to the widespread use of copper to control bacteria in the environment and hospitals.
V. CONCLUDING REMARKS The copper homeostatic mechanisms described herein ensure that bacteria are able to satisfy the needs of copper-requiring proteins whilst avoiding any excess that would otherwise engage in adventitious interactions. The use of copper-transporting P1B-type ATPases to export copper from the cytosol appears as a common theme amongst the different bacterial groups. All bacterial copper-dependent enzymes known to date are extracytoplasmic and for the vast majority it is not known how they acquire their copper. However, it is tempting to speculate that with analogy to eukaryotic cells, bacteria use P1B-type ATPases to mediate transport of available copper ions from the cytosol into a more specialized compartment, i.e., the cell envelope (or thylakoid), for incorporation into proteins whilst protecting the cytosol from copper-toxicity. Many bacteria also possess Atx1/CopZ-like copper-chaperones which may further contribute to copper-trafficking and -resistance. If these housekeeping copperhomeostatic systems are overwhelmed, some bacteria can invoke additional systems providing further resistance to increased copper stress. Copper homeostatic mechanisms are increasingly being linked to bacterial pathogenicity. However, the basis for this remains largely unknown and is anticipated to vary depending on the site of infection and the diverse survival tactics used by different bacteria. Understanding the environmental challenges that occur in an infected host and the mechanisms bacteria use to adapt to these challenges offers possibilities for the design of drugs that disrupt such mechanisms thereby allowing host clearance of the infecting organism. Furthermore, there is a new appreciation that copper may be used as a means of controlling bacterial growth, particularly with respect to controlling antibiotic-resistant strains of bacteria (such as MRSA) in clinical settings. An understanding of the mechanisms of copper homeostasis and resistance in bacterial pathogens is therefore needed to better inform future control strategies and offer the possibility of improving current copperbased treatments. Both Ag(I) and Cu(I) are chemically similar and in many cases appear to be treated interchangeably; many of the proteins involved
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in copper-resistance also protect against silver-toxicity. Clearly this has implications regarding the wide and uncontrolled use of both copper and silver products in the environment and the potential for the development of more resistant bacteria.
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Percival, S. (1998). Copper and immunity. Am. J. Clin. Nutr. 67, S1064–S1068. Petersen, C., and Mller, L. B. (2000). Control of copper homeostasis in Escherichia coli by a P-type ATPase, CopA, and a MerR-like transcriptional activator, CopR. Gene 261, 289. Phung, L. T., Ajlani, G., and Haselkorn, R. (1994). P-type ATPase from the cyanobacterium Synechococcus 7942 related to the human Menkes and Wilson disease gene products. PNAS 91, 9651–9654. Pontel, L. B., Audero, M. E. P., Espariz, M., Checa, S. K., and Soncini, F. C. (2007). GolS controls the response to gold by the hierarchical induction of Salmonella-specific genes that include a CBA efflux-coding operon. Mol. Microbiol. 66, 814–825. Portmann, R., Magnani, D., Stoyanov, J. V., Schmechel, A., Multhaup, G., and Solioz, M. (2004). Interaction kinetics of the copper-responsive CopY repressor with the cop promoter of Enterococcus hirae. J. Biol. Inorg. Chem. 9, 396–402. Portmann, R., Poulsen, K., Wimmer, R., and Solioz, M. (2006). CopY-like copper inducible repressors are putative ‘‘winged helix’’ proteins Biometals 19, 61–70. Pufahl, R. A., Singer, C. P., Peariso, K. L., Lin, S. J., Schmidt, P. J., Fahrni, C. J., Culotta, V. C., Penner-Hahn, J. E., and O’Halloran, T. V. (1997). Metal ion chaperone function of the soluble Cu(I) receptor Atx1. Science 278, 853–856. Radford, D. S., Kihlken, M. A., Borrelly, G. P. M., Harwood, C. R., Brun, N. E., and Cavet, J. S. (2003). CopZ from Bacillus subtilis interacts in vivo with a copper exporting CPx-type ATPase CopA. FEMS Microbiol. Lett. 220, 105–112. Rae, T. D., Torres, A. S., Pufahl, R. A., and O’Halloran, T. V. (2001). Mechanism of Cu,Znsuperoxide dismutase activation by the human metallochaperone hCCS. J. Biol. Chem. 276, 5166–5176. Rapisarda, V. A., Montelongo, L. R., Farias, R. N., and Massa, E. M. (1999). Characterization of an NADH-linked cupric reductase activity from the Escherichia coli respiratory chain. Arch. Biochem. Biophys. 370, 143–150. Rapisarda, V. A., Chehin, R. N., De Las Rivas, J., Rodriguez-Montelongo, L., Farias, R. N., and Massa, E. M. (2002). Evidence for Cu(I)-thiolate ligation and prediction of a putative copper-binding site in the Escherichia coli NADH dehydrogenase-2. Arch. Biochem. Biophys. 405, 87–94. Reeve, W. G., Tiwari, R. P., Kale, N. B., Dilworth, M. J., and Glenn, A. R. (2002). ActP controls copper homeostasis in Rhizobium leguminosarum bv. viciae and Sinorhizobium meliloti preventing low pH-induced copper toxicity. Mol. Microbiol. 43, 981–991. Rensing, C., and Grass, G. (2003). Escherichia coli mechanisms of copper homeostasis in a changing environment. FEMS Microbiol. Rev. 27, 197–213. Rensing, C., Mitra, B., and Rosen, B. P. (1997). The zntA gene of Escherichia coli encodes a Zn(II)-translocating P-type ATPase. PNAS 94, 14326–14331. Rensing, C., Sun, Y., Mitra, B., and Rosen, B. P. (1998). Pb(II)-translocating P-type ATPases. J. Biol. Chem. 273, 32614–32617. Rensing, C., Ghosh, M., and Rosen, B. P. (1999). Families of soft-metal-ion-transporting ATPases. J. Bacteriol. 181, 5891–5897. Rensing, C., Fan, B., Sharma, R., Mitra, B., and Rosen, B. (2000). CopA: An Escherichia coli Cu(I)-translocating P-type ATPase. PNAS 97, 652–656. Roberts, S. A., Weichsel, A., Grass, G., Thakali, K., Hazzard, J. T., Tollin, G., Rensing, C., and Montfort, W. R. (2002). Crystal structure and electron transfer kinetics of CueO, a multicopper oxidase required for copper homeostasis in Escherichia coli. PNAS 99, 2766–2771. Rosenzweig, A. C., Huffman, D. L., Hou, M. Y., Wernimont, A. K., Pufahl, R. A., and O’Halloran, T. V. (1999). Crystal structure of the Atx1 metallochaperone protein at 1.02 A resolution. Structure 7, 605–617. Rouch, D., Camakaris, J., and Lee, B. (1989). Copper transport in Escherichia coli. In ‘‘Metal Ion Homeostasis: Molecular Biology and Chemistry’’ (D. Hamer and D. Winge, Eds.), pp. 469–477. Alan R Liss, New York.
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Tottey, S., Harvie, D. R., and Robinson, N. J. (2005). Understanding how cells allocate metals using metal sensors and metallochaperones. Acc. Chem. Res. 38, 775–783. Tsai, K., Yoon, K., and Lynn, A. (1992). ATP-dependent cadmium transport by the cadA cadmium resistance determinant in everted membrane vesicles of Bacillus subtilis. J. Bacteriol. 174, 116–121. Tsivkovskii, R., MacArthur, B. C., and Lutsenko, S. (2001). The Lys1010-Lys1325 fragment of the Wilson’s disease protein binds nucleotides and interacts with the N-terminal domain of this protein in a copper-dependent manner. J. Biol. Chem. 276, 2234–2242. Tufft, L. S., Nockels, C. F., and Fettman, M. J. (1988). Effects of Escherichia coli on iron, copper, and zinc metabolism in chicks. Avian Dis. 32, 779–786. Uzzau, S., Bossi, L., and Figueroa-Bossi, N. (2002). Differential accumulation of Salmonella [Cu, Zn] superoxide dismutases SodCI and SodCII in intracellular bacteria: Correlation with their relative contribution to pathogenicity. Mol. Microbiol. 46, 147–156. van der Oost, J., von Wachenfeld, C., Hederstedt, L., and Saraste, M. (1991). Bacillus subtilis chytochrome oxidase mutants: Biochemical analysis and genetic evidence for two aa3type oxidases. Mol. Microbiol. 5, 2063–2072. Vats, N., and Lee, S. F. (2001). Characterization of a copper-transport operon, copYAZ, from Streptococcus mutans. Microbiology 147, 653–662. Voskoboinik, I., Mar, J., Strausak, D., and Camakaris, J. (2001). The regulation of catalytic activity of the Menkes copper-translocating P-type ATPase. J. Biol. Chem. 276, 28620–28627. Waldron, K. J., Tottey, S., Yanagisawa, S., Dennison, C., and Robinson, N. J. (2007). A periplasmic iron-binding protein contributes toward inward copper supply. J. Biol. Chem. 282, 3837–3846. Ward, S. K., Hoye, E. A., and Talaat, A. M. (2008). The global responses of Mycobacterium tuberculosis to physiological levels of copper. J. Bacteriol. 190, 2938–2946. Wernimont, A., Huffman, D., Finney, L., Demeler, B., O’Halloran, T., and Rosenzweig, A. (2003). Crystal structure and dimerization equilibria of PcoC, a methionine-rich copper resistance protein from Escherichia coli. J. Biol. Inorg. Chem. 8, 185–194. Wiethaus, J., Wildner, G. F., and Masepohl, B. (2006). The multicopper oxidase CutO confers copper tolerance to Rhodobacter capsulatus. FEMS Microbiol. Lett. 256, 67–74. Wong, P. C., Waggoner, D., Subramaniam, J. R., Tessarollo, L., Bartnikas, T. B., Culotta, V. C., Price, D. L., Rothstein, J., and Gitlin, J. D. (2000). Copper chaperone for superoxide dismutase is essential to activate mammalian Cu/Zn superoxide dismutase. PNAS 97, 2886–2891. Wunderli-Ye, H., and Solioz, M. (2001). Purification and functional analysis of the copper ATPase CopA of Enterococcus hirae. Biochem. Biophys. Res. Commun. 280, 713–719. Xue, Y., Davis, A. V., Balakrishnan, G., Stasser, J. P., Staehlin, B. M., Focia, P., Spiro, T. G., Penner-Hahn, J. E., and O’Halloran, T. V. (2008). Cu(I) recognition via cation-[pi] and methionine interactions in CusF. Nat. Chem. Biol. 4, 107–109. Yamamoto, K., and Ishihama, A. (2005). Transcriptional response of Escherichia coli to external copper. Mol. Microbiol. 56, 215–227. Yoon, K., Hoon Byeon, J., Park, J., and Hwang, J. (2007). Susceptibility constants of Escherichia coli and Bacillus subtilis to silver and copper nanoparticles. Sci. Total Environ. 373, 572–575. Yuan, D. S., Stearman, R., Dancis, A., Dunn, T., Beeler, T., and Klausner, R. D. (1995). The Menkes/Wilson disease gene homologue in yeast provides copper to a ceruloplasminlike oxidase required for iron uptake. PNAS 92, 2632–2636. Zgurskaya, H. I., and Nikaido, H. (1999). AcrA is a highly asymmetric protein capable of spanning the periplasm. J. Mol. Biol. 285, 409–420.
CHAPTER
9 Pathogen Surveillance Through Monitoring of Sewer Systems Ryan G. Sinclair,*,1 Christopher Y. Choi,† Mark R. Riley,† and Charles P. Gerba*
Contents
I. Introduction A. Monitoring for human pathogens in sewage II. Potential Biological Agents in Sewage A. Human pathogens secreted in bodily fluids B. Duration of release and concentration in bodily fluids and skin III. Concentration of Biological Agents in Sewage IV. Laboratory Methods and Detection A. Detection of pathogens B. Survival of pathogens in sewer systems C. Lessons learned from poliovirus: Monitoring as an early warning system D. Differentiation of vaccine and virulent strains V. Conclusions: The Probability of Detection Acknowledgments References
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* Department of Soil, Water and Environmental Science, University of Arizona, Tucson, Arizona 85721 { 1
Department of Agricultural and Biosystems Engineering, University of Arizona, Tucson, Arizona 85721 Corresponding author: University of Arizona, 2601 E. Airport Drive, Tucson, AZ 85706
Advances in Applied Microbiology, Volume 65 ISSN 0065-2164, DOI: 10.1016/S0065-2164(08)00609-6
#
2008 Elsevier Inc. All rights reserved.
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I. INTRODUCTION It is now possible to monitor sewage systems for pathogen occurrence in a community. An epidemiological approach to monitoring sewer systems is especially relevant for an early warning of pathogens used as biological weapons. In many situations, bioterrorist contamination events will result in the pathogen shedding to wastewater before a community level epidemic begins. Detecting the organism early allows the governments to respond on time and eliminate a potential catastrophe.
A. Monitoring for human pathogens in sewage Monitoring of human pathogens in sewage is possible because they may be excreted in a range of bodily fluids, skin, and hair during active infection (Feachem et al., 1983). All of these materials will find their way into sewage systems during the process of waste elimination (toilet flushing) and cleaning (e.g., bathing, hand washing). In addition to release during active infection, pathogens can be washed into sewage systems from cleaning of indoor (floor washing, kitchen sink use) and outdoor (auto washing, driveway cleaning, storm water collection) facilities. Thus, sewer systems collect pathogens from over a wide area to a common carrier, where they are transported to a central facility for processing. Wastewater presents a time dynamic collection point where many physical, chemical, and biological substances of our society are brought to a central location. Monitoring of centralized wastewater allows detection of intentional, natural, or accidental contamination events. Because of recent bioterrorism concerns in the U.S., routine monitoring is potentially useful since it can result in better preparedness of utilities and the public health response system (Meinhardt, 2005). The qualitative microbial risk assessment (QMRA) framework can be used as a tool to develop and interpret this type of wastewater monitoring system. Because the threat level drives the risk assessment analysis, a monitoring system should be coordinated with findings from modeling studies on the survival and dispersion of contaminants (Kim et al., 2007; Romero et al., 2008; Sinclair et al., 2008), the contaminant point of introduction (Danneels and Finley, 2004), the health risk (Haas et al., 1999), and the locations of early warning systems/ sensors in wastewater and water treatment systems (Murray et al., 2004). A recent U.S. National Research Council study called for more resilient design/operation of wastewater and drinking water systems (USNRC, 2007) to improve response and recovery from adverse water quality events in collection systems, water distribution systems, and water/ wastewater treatment systems. Monitoring programs for pathogens or surrogates could potentially aid in the accomplishment of these goals.
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The aim of this review of published literature and reports is to assess the feasibility of monitoring sewage systems as an early warning system for the release of pathogens from an intentional, natural, or accidental biological contamination event. We address issues from a QMRA perspective and explore methods to detect and monitor pathogens in wastewater. The review presents our conclusions on: (1) the potential biological agents that might be released into a sewage system, (2) the likely background level of those agents in sewage, (3) laboratory methods and detection, and (4) the probability of detecting select biological agents in sewage.
II. POTENTIAL BIOLOGICAL AGENTS IN SEWAGE A wide variety of pathogenic organisms pass through municipal wastewater treatment systems. One study found that a single toilet flush containing poliovirus was detectable at a nearby treatment plant for more than 4 days (Ranta et al., 2001). The toilet flush study was designed to replicate the number of virus released from an infected individual. Pathogenic microorganisms can also grow in the host but not produce sickness in the infected host. It is estimated that 50% or less of those individuals infected with enteric viruses or bacteria actually become ill (Haas et al., 1999). In the case of some respiratory pathogens, 90% or more of the persons infected will become ill (Belshe, 1991). During the growth of the organism in the host, the organism will be found in various organs and bodily fluids. Organisms transmitted by the fecal–oral route are usually excreted in large numbers in the feces, since the initial or primary site of replication is in the intestinal tract. However, this does not preclude their replication in other parts of the body. For example, enteroviruses (e.g., poliovirus) will replicate in nerve tissue causing paralytic disease, while Hepatitis A virus will replicate in the liver causing damage there (Belshe, 1991). Respiratory infections are usually the result of replication of the organism in the nose, throat, or lungs. Infection of other organs of the body often leads to the presence of the organisms in the blood and then the urine after their elimination by the kidneys. This explains the occurrence of insect-borne encephalitis viruses and enteric viruses in the urine (Pichichero et al., 1998). Any type of infection (Fig. 9.1) within a community is likely to lead to pathogen excretion in bodily fluids/substances and therefore, transported into the community sewage system. This review considers biological agents prioritized by the Centers for Disease Control (CDC) as potential biological weapons that could be used by terrorists (Table 9.1 and 9.2). They are listed in three categories (i.e., A, B, and C) of decreasing concern. Category A agents require the most intensive public preparedness efforts due to the potential for mass
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Symptomatic infection • Death or mortality • Severe disease • Moderate severity • Mild illness
Clinical disease
Asymptomatic infection • Infection without clinical illness
Sub-clinical disease
• Exposure without colonization
FIGURE 9.1
No infection
Outcomes of exposure to a microbial infection.
causalities, public fear, and civil disruption. Category B agents are also moderately easy to spread, but have lower mortality rates. Category C agents do not present a high public health threat, but could emerge as future threats (Rotz et al., 2002). Many other pathogenic agents are present in sewage, but not on the CDC select agent list. Table 9.2 lists some common blood and respiratory agents and emerging pathogens, all of which could potentially be engineered for mass dissemination and detected through monitoring of wastewater. The methods described in this paper apply to many other pathogens and are not limited to those agents listed in Tables 9.1 and 9.2.
A. Human pathogens secreted in bodily fluids A literature search was conducted to determine the occurrence of the agents in bodily fluids, feces, skin, and sewage. As indicated in Table 9.3 and a previous publication (Sinclair et al., 2008), many select agents may occur in bodily excretions or secretions even though this may not be their primary site of replication. It would appear that all of the viral agents are excreted in the urine and most of the bacterial agents in the feces or saliva. Since none of the organisms cause enteric infections they have seldom been sought in sewage, however, Bacillus anthracis and Yersina pestis (plague) have been detected in sewage. The source of B. anthracis spores in the sewage was believed to be from an African import tannery operation (Perone and Gelosa, 1982) and presumably not from enteric infections, which would normally result in the presence of spores in the feces. Category B agents differ in that, and they include many enteric pathogens which are excreted in large numbers in the feces (Table 9.3). All of the other agents in this category appear to be excreted in the feces; many of the viral agents are excreted in the urine. No studies
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TABLE 9.1
a
253
The center for disease control select agents (Rotz et al., 2002)
Category A
Category B
Category C
Anthrax Bacillus anthracis Botulism Clostridium botulinum Plague Yersinia pestis Smallpox Variola major Tularemia Francisella tularensis Hemorrhagic fever virusa Arenaviridae Bunyaviridae Filoviridae Flaviviridae Lassa fever Hantavirus Dengue fever Ebola Marburg
Brucellosis Brucella abortus Water and Food-borne agents Enteroviruses Poliovirus and Rotavirus Salmonellosis Salmonella Caliciviruses Hepatitis A virus Protozoan parasites Cryptosporidium parvum Giardia lamblia Toxoplasma Microsporidium Glanders Burkholderia mallei Psittacosis Chlamydia psittaci Q fever Coxiella burnetii Typhus fever Rickettsia prowazekii Viral Encephalitis West Nile La Crosse Venezuelan equine encephalitis Japanese encephalitis
Nipah virus Tick-borne HFV Crimean-Congo HFV Tick-borne encephalitis viruses Yellow fever Multidrug resistant TB Influenza Other Rickettsias Rabies
Hemorrhagic fever virus (HFV).
were found that report examining sewage for their presence. The Category C viral agents appear to be excreted in the saliva and urine (Tables 9.3 and 9.4). No references for the presence of these agents in sewage could be found. Some typical blood-borne agents such as Hepatitis B virus (Alter et al., 1977) and Human Immuno-Deficiency virus (Levy, 1989) have been detected in sewage by molecular methods (Table 9.4). The coronavirus, which causes Severe Acute Respiratory Disease (SARS), is
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TABLE 9.2 Nonenteric pathogens found in sewage and other emerging agents of concern Nonenteric agents
Emerging agents
Severe Acute Respiratory Syndrome (SARS) John Cunningham virus ( JC Virus) Human Immuno-deficiency Virus (HIV) Hepatitis B Virus (HBV)
Parvoviruses Picobirnaviruses Enteroviruses types 78–100 Torque teno virus (TTV)
also excreted in the feces and other bodily fluids such as tears (Loon et al., 2004; Wang et al., 2005) (Table 9.4).
B. Duration of release and concentration in bodily fluids and skin The duration and concentration of pathogens released by a host during the course of an infection varies, with greater numbers being released in more severe infections. After infection, the number of organisms released usually rises rapidly reaching a peak when the symptoms appear in symptomatic infections. This is usually followed with a long decline in the amount of agent released by the host as long as death does not occur. For example, poliovirus appears in the throat and feces 7–10 days before clinical illness (fever) is apparent and may be excreted for more than 30 days after infection (Fig. 9.2). Poliovirus will also be detectable in the blood and urine during the course of infection (Pichichero et al., 1998). Hepatitis A virus appears in the stool of infected individuals 2–3 weeks before clinical illness (Belshe, 1991). Parainfluenza, a virus related to influenza, can be detected in nasal secretions in less than 24 h after infection and up to 2 weeks afterward (Belshe, 1991). In the case of SARS, the virus may still be present in the feces for 37 days after infection (Holmes, 2003). Variola major, the virus that causes smallpox, is released for up to 19 days after infection at concentrations of 102–105 per ml of urine (Table 9.5) (Sarkar et al., 1973). In many infections, the greatest concentrations are released during the first few days after the initial infection. Brucella abortus is excreted in concentrations as high as 106 per ml of urine for up to 12 weeks (Table 9.6). Marburg virus and flaviviruses are excreted in the urine of animals for 10–12 days. In summary, all of the nonenteric agents of interest (Categories A, B, and C) are released in the host for at least days to weeks in concentrations likely to be detectable in sewage systems (Table 9.6) (Sinclair et al., 2008). Most of the existing data on the occurrence and concentration of pathogens was gathered using culture of viable or infective organisms. Molecular methods such as the polymerase chain reaction (PCR) or
TABLE 9.3 Select category B and C agents found in human bodily fluids and sewage
a b c
Agent
Category
Urine
Feces
Saliva
Sewage
Reference
C. psittaci
B
?
Yesa
?
?
C. burnetii Viral encephalitis Nipah virus Rabies Influenza
B B
Yes Yes
Yesb Yesc
? ?
? ?
Midura and Arnon (1976); Anderson (1996); Smith et al. (2005) Tylewska-Wierzbanowska and Kruszewska (1993) Mathur et al. (1995)
C C C
Yes Yes ?
? ? Yesc
Yes Yes Yes
? ? ?
Chua et al., (2002) Wacharapluesadee and Hemachudha (2002) Buchy et al. (2007)
Nasal. Semen. Animals.
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TABLE 9.4 Occurrence of other agents of interest in bodily fluids Agent
Urine
Feces
Saliva
Sewage
Reference
Severe Acute Respiratory Syndrome John Cunningham virus (poliovirus) Human Immunodeficiency Virus Hepatitis B virus
?
Yes
Yes
?
He et al. (2007); Petrich et al. (2006)
Yes
?
?
Yes
Coleman et al. (1980)
Yes
Yes
Yes
Yes
?
?
Yes
Yes
Levy (1989); Yolken et al. (1991) Alter et al. (1977); Bancroft et al. (1977); Arvanitidou et al. (1998)
Virus detected in
Clinical illness (fever) Blood Throat Feces 0
7
12 17 Days after infection
23
FIGURE 9.2 Occurrence of nonpolio enterovirus in bodily fluids and feces during the course of infection (interpreted from Pichichero et.al., 1998).
immuno-chemical methods (enzyme-linked immunoassays or ELISA) can detect both infectious and noninfectious organisms. These molecular techniques can detect concentrations from 1 to 10,000 greater than culture methods because some of the organisms may be inactivated (dead) or may not be able to grow on the selected media (bacteria) or cell culture (used for viruses). In the case of enteric viruses, the ratio of viruses detected by infectivity assay may be 100–50,000 times less than that detected by a molecular method (Ward et al., 1984). This is because cell culture methods have a low efficiency in virus quantification from clinical and environmental samples; however, they do provide a robust measure of viral activity not feasible with molecular methods. Agents causing enteric and respiratory infections are released in large numbers in feces and respiratory secretions (Table 9.4). Many of the
TABLE 9.5 Concentration of select agents in sewage and duration of agent release after infection of individuals. see Sinclair et al., (2008) for the following category A agents: Variola major, Hantavirus, Marburg virus, and Flavivirus Agent
a b
Category
Fluid
Concentrationa
Duration
Reference
Paton et al. (1983) Takahashi et al. (1988) Bicknell and Bell (1979); Carmichael and Joubert (1988); Serikawa et al. (1981) Mathur et al. (1995)
C. Botulinum C. Psittaci B. Abortus
A B B
Feces Feces Urine
10 102–103 102–106
? 28 daysb 8–12 weeks
Japanese encephalitis Enteroviruses Protozoa C. Burnetii
B
Urine
1–4
3 days
B B B
Feces Feces Feces
108–1012 106–107 103–104
Weeks to Months Weeks to Months 7 days
Influenza
C
Nasal
105–107
5 days to Weeks
per ‘‘milliliter’’ of volume or ‘‘gram’’ of solid. Animals.
8
Maier et al. (2000) Maier et al. (2000) Tylewska-Wierzbanowska and Kruszewska (1993) Belshe (1991)
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TABLE 9.6
Titer of smallpox virus in urine (Sarkar et al., 1973)
Days after infection
Titer(mL)
3 4 5 6 7 8 10 15 19 20
103–105 102–105 102–104 101–104 101–103 101–102 101–102 101–102 101 0
TABLE 9.7 Factors that affect concentration of the biological agent in sewage
Site of replication in the host GI, upper respiratory, nose, skin, internal organs Duration of release from the host Concentration in the source Incidence of disease in the population Water use per capita Season Survival in the sewer system
enteric viruses such as the enteroviruses and adenoviruses may replicate both in the intestinal and respiratory tract. Using molecular methods the number of enteric viruses detected can approach peak concentrations of 1012 organisms per gram of stool while protozoa can approach 106–107 per gram. Cultivatable enteric bacterial pathogens such as Salmonella may also occur in concentrations as large as 1011 per gram (Feachem et al., 1983). By infectivity assays, the concentration of respiratory viruses ranges from 105 to 107 per ml of respiratory secretion. Even blood-borne viruses such as HIV will be found in the feces of infected persons (Ansari et al., 1992) and it appears that many viruses will occur in the urine during infection of the host (Table 9.6), although these excreted viruses may not be infectious. Little information is available on the concentration of pathogenic viruses or bacterial agents of interest in the urine. The total amount of virus released by a person is, of course, also related to the amount of feces, urine, respiratory secretion, and skin that is released by the person. On average, a person excretes between 100 to 400 g of feces and 700–2000 ml of urine per day (Table 9.7).
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TABLE 9.8
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Sources of biological agents in sewers (Feachem et al., 1983)
Feces (100–400 g/person/day) Urine (700–2000 ml/day) Skin—from bath and hand washing Saliva, respiratory secretions Blood Food Wash water (kitchen, drains) Storm watera a
Some sewer systems are combined with the storm-water collection system.
A person with an enteric viral infection may excrete as many as 1014 viral particles per day and over 1015 during the course of an infection (Table 9.8). Nonenteric bacterial agents of interest appeared to be released in concentrations from 100 to 108 by viability assays (Boone and Gerba 2007). Respiratory pathogens end up in the feces from the swallowing of secretions. Ecological studies of bovine tuberculosis in badgers introduce the concept of ‘‘super-excretors,’’ which maintain the disease and pass infectious organisms in their stool or urine continuously. Super-excretors are individuals who excrete larger numbers than average of a pathogen during an infection. These super-excretors were almost exclusively animals with a progressive infection, which does not resolve and contributed to a higher mortality (Delahay et al., 2000). The occurrence of a similar ‘‘super-spreader’’ was also noted in a clinical epidemiological report of SARS in humans (Holmes, 2003).
III. CONCENTRATION OF BIOLOGICAL AGENTS IN SEWAGE The occurrence and concentration of pathogens in sewage is dependent upon a number of factors listed in Table 9.9. One of the most important considerations is the amount of pathogen released by a person daily from bodily fluid, feces, skin, and urine. Because one infected individual typically produces at least 100 g of feces per day, a pathogen present at 108 per gram will introduce at least 1010 or more of the pathogen into the sewer system. Logically, pathogens excreted in urine and feces will be released several times during a 24-h period. Enteric and respiratory pathogens are almost always detected in sewage because of the long duration of release from the host during infection, the large concentrations released from the host, and the many infections that are asymptomatic. Studies have shown that the types and concentration of enteric microorganisms in sewage is directly related to the incidence of disease in the
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TABLE 9.9
a
Comparative occurrence of enteric agents (category B) in feces and sewage
Agent(s)
Feces (per gram)
Stoola
Sewage (100 ml)
Enteric viruses (infectivity assay) Enteric viruses (PCR assay) Giardia Cryptosporidium
108 1010–1012 106 106
1010 1012–1014 108 108
102 104–105 10–102 0.1–102
100 g stool (150 g average in the U.S.).
community (Riordan 1962; Sellwood et al., 1981). The concentration of enteric pathogens in sewage ranges from 0.1 to 100,000 per ml of sewage (Table 9.8). While many biological agents of interest have been detected in sewage (Table 9.3), the studies are limited and vary by location.
IV. LABORATORY METHODS AND DETECTION A. Detection of pathogens Culture based methods can be used for the detection of pathogens in wastewater, but they may take days to weeks to perform. Alternative molecular methods, such as the PCR, have been successful in detecting bacterial, viral, and protozoan pathogens in sewage without the need for cultivation (Gilbride et al., 2006). These new techniques detect live and dead organisms, have a high sensitivity for wastewater, and can reduce detection time to a few hours (He and Jiang, 2005; Holmes, 2003). Some promising new wastewater methods use nucleic acid microarrays or antibody/receptor technologies to detect multiple pathogens simultaneously (Boehm et al., 2007). Combining these multiplexed methods with fiberoptic sensors and lab-on-a-chip technology can allow utilities to rapidly screen, identify, and quantify multiple pathogens in real time. Because these technologies rely on PCR DNA techniques, the many interfering substances in raw sewage pose a problem. Without proper sample extraction, the sample analytes are exposed to many varying inhibitors, which can negatively impact the DNA isolation and amplification steps. These methods are also limited by their inability to differentiate between viable and nonviable or nonculturable organisms ( Josephson et al., 1993), a vital characteristic when assessing the microbial risk assessment for any given community. Certain methods are in development to automate the sample collection, sample processing, and concentration to separate analytes from inhibitors and deliver a suitable clean sample to a real-time detection microarray technology. These methods use latex beads, carbohydrates,
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anion exchange resins, or similar substances as part of sample collection and sample processing step (Straub and Chandler, 2003), but no fully automated method has been proposed for wastewater. A biosensor capable of identifying and quantifying a wide group of pathogens is necessary, but future development is needed in the areas of extraction from environmental samples, selection of a suitable target sequence of the pathogen (specificity), detection and differentiation of the signal from interfering sequences (sensitivity), and automation of all processes towards a functional real-time biosensor for wastewater (Gilbride et al., 2006).
B. Survival of pathogens in sewer systems A principal benefit of wastewater monitoring is that most pathogens of interest are expected to remain viable for at least several days in the sewerage environment (Table 9.10). Enteric and respiratory agents are particularly stable, while data is limited for viral encephalitis agents because transmission in water and other liquid media does not occur naturally. Using molecular methods, survival of the pathogens in the viable form is not necessary for their detection, thus increasing the length of time for which the pathogen may be detected. In the case of select TABLE 9.10
The Helsinki poliovirus experiment (Ranta et al., 2001)
Helsinki population ¼ 740,000 Sewage flow 2 108 l/day Contamination Event 5 1010 TCID50 Poliovirus vaccine Flushed down toilet in one liter volume 20 km from sewage treatment plant Detection Automatic sampler ¼ 200 ml per 5 106 liters of sewage flow Four samples pooled per day Concentrated from 400 to 1 ml before assay Result Virus was detected for the next 4 days (cell culture) Peak 24–48 h after flush Virus detected after passage of 800 million liters of sewage pass through system Conclusion Monitoring of sewage could detect 1 infected person in 10,000 Assumes: 108 infectious virus excreted by child in 4 days
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agents, knowing the presence of the organism in the sewer system may be all that is needed to trigger further investigation regardless of viability.
C. Lessons learned from poliovirus: Monitoring as an early warning system The benefits of pathogen monitoring in sewage have been recognized for poliovirus for more than 40 years. The relationship between the occurrence of poliovirus in sewage and clinical incidence of disease in a community was first noted in the late 1960s (Nelson et al., 1967). These early detection studies were designed as longitudinal epidemiological investigations to assess the success of polio vaccination campaigns (Riordan, 1962). The results of these studies demonstrated that a definite correlation exists among the isolation of enteroviruses in sewage, and the isolation of viruses in stools, and the number of recognized clinical cases within the community. Using cell culture assay techniques (which measure only infective viruses) and only grab samples (i.e., no steps to concentrate the sample) poliovirus could be detected when only 0.27–0.4% of the population was excreting the virus. It was also demonstrated that small outbreaks and epidemics of enterovirus and adenovirus disease within a community can be predicted by monitoring a community’s sewage. Virulent or wildtype (nonvaccine strain) poliovirus type 1 was detected in sewage 9 days before the first clinical case became evident (Kuwert et al., 1970). In an outbreak of Coxsackievirus B5, the virus was detected in the sewage 10 days before clinical cases were positive (Nelson et al., 1967). These studies make it clear that grab samples collected on a regular (weekly or every few days) basis could be used to assess the introduction of a new infectious agent in the community. This approach was later adapted to monitor the success of poliovirus vaccine campaigns internationally (WHO, 2003). To assess the sensitivity of poliovirus monitoring, one study (Ranta et al., 2001) flushed a one-time bolus of 1 l containing 2 1010 infective poliovirus type 1 vaccine strain down a toilet 20 km (12 miles) from the sewage plant (Table 9.11). Samples were automatically collected and assayed for the next 4 days. Infectious poliovirus was still detected after 800 million liters had passed through the system. The authors concluded that their monitoring system could detect one infected person in 10,000 residents of the community, assuming that 108 infective viruses are excreted by a child over a 4-day period of time. The study showed that pathogens appear to be greatly retarded in sewage systems, where a onetime event resulted in a detection period over 4 days. The pathogen was also easily detected in 200-ml samples for every 5 106 l of sewage flow. Surveillance of poliovirus in sewage has been used by several nations to assess the success of vaccination programs and to identify the potential
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TABLE 9.11 Survival time of pathogens in the environment (water, feces, urine, sewage) (Belanov et al., 1996; Belshe, 1991; Mitscherlich and Marth, 1984; Sinclair et al., 2008) Organism
Days of survival
B. anthracis C. botulinum Y. pestis Variola major (smallpox) F. tularensis Marburg virus (surfaces) Enteric pathogens B. mallei Psittacosis (C. psittaci) Q fever (C. burnetti) Typhus fever (Rickettsia typhi) Influenza (surfaces)
Weeks to years Weeks Days Weeks to months 12–60 days 4–5 days Days to months 28–35 days Days 30–1000 days Hours to days 3 days
need for vaccination to prevent outbreaks (Deshpande et al., 2003; Manor et al., 1999; Tambini et al., 1993). The World Health Organization has published guidelines for the environmental surveillance of poliovirus circulation (WHO, 2003). These guidelines assume that a single infected person will excrete 107 polioviruses per day and that one person infected in 100 could be detected using an infectivity assay without concentrating the sewage. However, if the tested sample is concentrated 100 fold then one infected person among 10,000 could be detected. The Public Health Laboratories of Israel have been conducting an environmental surveillance of sewage on a monthly basis since 1989 (Manor et al., 1999) to assess the spread of the wild type poliovirus strains capable of causing paralytic disease. This was done to determine the success and need for vaccination programs. Between 1989 and 1998, four ‘‘silent’’ separate episodes of wild-type poliovirus circulation were detected when no clinical cases were observed. The study described how surveillance of the sewage is much more effective than surveillance of clinical cases. The greater sensitivity of sewage surveillance was also validated in Mumbai, India where wild type poliovirus was detected 3 months before any clinical cases were observed (Deshpande et al., 2003).
D. Differentiation of vaccine and virulent strains In the poliovirus surveillance of sewage it is necessary to differentiate between vaccine strains and wild type strains of the virus. In the past this has been accomplished by using different cell lines or incubation
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conditions to limit the growth of the vaccine strains. However, today this can be accomplished by the use of molecular methods and sequence analysis. Sequences amplified directly from processed sewage samples by PCR using primer pairs specific for the indigenous type 1 genotype could be used to assess its occurrence in the presence of vaccine strains (Tambini et al., 1993). Vaccine strains have unique sequences from wild type strains of pathogens allowing easy differentiation. In addition, sequence analysis of sewage isolations has been shown useful in tracking the spread of wild type poliovirus from one country and community to another (Deshpande et al., 2003; Manor et al., 1999). This review of poliovirus is offered here as a case study and justification for the use of monitoring additional CDC select biological agents. With current molecular techniques and updated concentration methods, a much greater sensitivity and specificity can be achieved for poliovirus and many other CDC select agents.
V. CONCLUSIONS: THE PROBABILITY OF DETECTION Studies with poliovirus demonstrated the feasibility of how monitoring sewage for virulent pathogens can be used to assess the success of vaccine programs. This review identified three important benefits of developing a wastewater monitoring system. Sewage surveillance system has been shown to be more sensitive than reporting of clinical cases of serious illness in a community. It was also demonstrated that pathogens can be greatly retarded in a sewage systems allowing a detection time over many days for a one-time release into a sewage system. Finally, it was shown that infectivity assays have the ability to detect one infected person in 10,000 individuals. Sewage surveillance can detect the presence or increased amount of infections from enteric pathogens excreted in the feces or urine during infection. However, the success of such a surveillance system for nonenteric pathogens has not been demonstrated, although they have been found in sewage. The sensitivity of a sewage surveillance system will depend on several important factors including the amount and duration of the agent released into the sewers, the frequency of monitoring, and the sensitivity of the monitoring method. Nonenteric pathogens are released from the host for a minimum of several days. This has already been demonstrated for HIV, hepatitis B, and Y. pestis (see Tables 9.2 and IV). Given this fact and the expected several day retardation in sewer systems, all or most of the nonenteric category agents will be present in the sewer system if there is an infection in the population served by the sewer system. Based upon the conclusions of the Helsinki experiment, which measured infectious poliovirus
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(Table 9.11), one individual excreting 108 infectious virus per gram of feces for a period of 4 days could be identified in a population of 10,000. If we consider the concentration and amount of infectious agent in the fluid or feces released during infection, this same sensitivity should be achieved with the agents of smallpox, Brucella, botulism and perhaps influenza. Based on existing information in Table 9.5 at least one person in 100 could be detected for most of the agents for which information is available. Because many of the agents take several days to detect by conventional culture methods the preferred detection system would be by a rapid, but highly specific method such as the quantitative real time PCR or other similar molecular detection system. Because PCR can detect both culturable and nonculturable organisms, it can be expected to be more sensitive than methods that have been used in the past for sewage surveillance. Use of PCR should increase sensitivity by as much as 50,000 over cultivation methods (Ward et al., 1984). Also, when using PCR to detect viruses in sewage, a 10fold loss in sensitivity is likely with current methods. This loss is due to interfering substances present in the sewage, but still leaves a method that may be 5000 times more sensitive than conventional culture methods. Increasing the volume of wastewater that is tested may also increase the sensitivity of current methods. Technology is available (Hurst and Crawford, 2002) which allows for the concentration of bacteria and viruses from up to 10 l of raw sewage. Thus, increasing the volume analyzed from 400 to 4000 ml could increase the sensitivity of detection another 10-fold. Surveillance of pathogens in wastewater has several advantages over aerosol and other monitoring methods. Longer survival times in soil, water, and wastewater (Sinclair et al., 2008) facilitate a retardation of pathogens in sewage which allows a longer sampling window than aerosols where organisms are much more susceptible to factors such as settling, desiccation, and relative humidity. Additionally, wastewater is collected in a central location, allowing monitoring to be defined or subdivided to specific areas. Lastly, wastewater systems can include many pathogens originating in aerosol, surface water, tap water, or fomites as storm-water and watersheds will often flow into sewerage systems. Of course background levels and alert levels of the agents of interest would have to be established. Most agents of interest are likely to occur at one time or another in wastewater or at least have some normal range of background. Further research would be needed to determine what these levels might be and normal variation of concentrations of the agents in wastewater. The types and concentration would be expected to vary by location and the size of the population, area served and type of connections (e.g., the presence of a slaughterhouse may increase the likelihood of finding animal pathogens). In summary, given the potential enhanced sensitivity of molecular methods and current abilities to test larger volumes of all of the CDC
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select agents of interest (enteric and nonenteric), it is possible to detect if an infected individual enters a monitored population. Although the concentration and duration of release of all of the agents of interest are not known, it is still possible to detect at least one infection in populations of 1000 or more. This monitoring is especially useful when combined with other components of the QMRA framework such as modeling of sewage dispersion, back calculation of contaminant point of introduction, and calculations of the health risk.
ACKNOWLEDGMENTS This study was supported by the United States Defense Advanced Research Projects Agency, the Center for Advancing Microbial Risk Assessment funded by the United States Environmental Protection Agency Science to Achieve Results, and the United States Department of Homeland Security University Programs grant number R3236201. Ryan Sinclair was supported through the National Research Council’s Research Associate Program with funding from the United Sates Department of Homeland Security.
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Buchy, P., Mardy, S., Vong, S., Toyoda, T., Aubin, J. T., Miller, M., Touch, S., Sovann, L., Dufourcq, J. B., Richner, B., Tu, P. V., Tien, N. T., et al. (2007). Influenza a/h5n1 virus infection in humans in Cambodia. J. Clin. Virol. 39, 164–168. Carmichael, L. E., and Joubert, J. C. (1988). Transmission of Brucella canis by contact exposure. Cornell Vet. 78, 63–73. Chua, K. B., Lek Koh, C., Hooi, P. S., Wee, K. F., Khong, J. H., Chua, B. H., Chan, Y. P., Lim, M. E., and Lam, S. K. (2002). Isolation of Nipah virus from Malaysian island flyingfoxes. Microbes Infect. 4, 145–151. Coleman, D. V., Wolfendale, M. R., Daniel, R. A., Dhanjal, N. K., Gardner, S. D., Gibson, P. E., and Field, A. M. (1980). A prospective study of human polyomavirus infection in pregnancy. J. Infect. Dis. 142, 1–8. Danneels, J. J., and Finley, R. E. (2004). Assessing the vulnerabilities of U.S. drinking water systems. J. Contemp. Water Res. Educ. 129, 8–12. Delahay, R. J., Langton, S., Smith, G. C., Clifton-Hadley, R. S., and Cheeseman, C. L. (2000). The spatio-temporal distribution of Mycobacterium bovis (bovine tuberculosis) infection in a high-density badger population. J. Anim. Ecol. 69, 428–441. Deshpande, J. M., Shetty, S. J., and Siddiqui, Z. A. (2003). Environmental surveillance system to track wild poliovirus transmission. Appl. Environ. Microbiol. 69, 2919–2927. Feachem, R. G., Bradley, D. J., Garelick, H., and Mara, D. D. (1983). ‘‘Sanitation and Disease. Health Aspects of Excreta and Wastewater Management.’’ Wiley, Washington DC, USA. Gilbride, K. A., Lee, D. Y., and Beaudette, L. A. (2006). Molecular techniques in wastewater: Understanding microbial communities, detecting pathogens, and real-time process control. J. Microbiol. Methods 66, 1–20. Haas, C., Rose, J., and Gerba, C. (1999). ‘‘Quantitative Microbial Risk Assessment.’’ Wiley, New York, USA. He, J. W., and Jiang, S. (2005). Quantification of Enterococci and human adenoviruses in environmental samples by real-time PCR. Appl. Environ. Microbiol. 71, 2250–2255. He, Z., Zhuang, H., Zhao, C., Dong, Q., Peng, G., and Dwyer, D. E. (2007). Using patientcollected clinical samples and sera to detect and quantify the severe acute respiratory syndrome coronavirus (SARS-cov). Virol. J. 4, 32. Holmes, K. V. (2003). SARS coronavirus: A new challenge for prevention and therapy. J. Clin. Invest. 111, 1605–1609. Hurst, C. J., and Crawford, R. L. (2002). ‘‘Manual of Environmental Microbiology.’’ 2nd ed. ASM Press, Washington, DC, USA. Josephson, K. L., Gerba, C. P., and Pepper, I. L. (1993). Polymerase chain reaction detection of nonviable bacterial pathogens. Appl. Environ. Microbiol. 59, 3513–3515. Kim, M., Choi, C. Y., and Gerba, C. P. (2007). Source tracking of microbial intrusion in water systems using artificial neural networks. Water Res. 42, 1308–1314. Kuwert, E., Hoher, P. G., Worringe, W., Bohlmann, H. G., and Thraenha, O. (1970). Oral polio vaccination—Comparison of serological findings after double and triple application of a trivalent live vaccine. Deutsche Medizinische Wochenschrift 95, 2505. Levy, J. A. (1989). Human immunodeficiency viruses and the pathogenesis of AIDS. JAMA 261, 2997–3006. Loon, S. -C., Teoh, S. B. C., Oon, L. L. E., Se-Thoe, S. -Y., Ling, A. -E., Leo, S. -Y., and Leong, H. -N. (2004). The severe acute respiratory syndrome coronavirus in tears. Br. J. Opthamol. 88, 861–863. Maier, R. M., Pepper, J. L., and Gerba, C. P. (2000). ‘‘Environmental Microbiology.’’ Academic Press, San Diego, California, USA. Manor, Y., Handsher, R., Halmut, T., Neuman, M., Bobrov, A., Rudich, H., Vonsover, A., Shulman, L., Kew, O., and Mendelson, E. (1999). Detection of poliovirus circulation by environmental surveillance in the absence of clinical cases in Israel and the Palestinian authority. J. Clin. Microbiol. 37, 1670–1675.
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Tambini, G., Andrus, J. K., Marques, E., Boshell, J., Pallansch, M., De Quadros, C. A., and Kew, O. (1993). Direct detection of wild poliovirus circulation by stool surveys of healthy children and analysis of community wastewater. J. Infect. Dis. 168, 1510–1514. Tylewska-Wierzbanowska, S., and Kruszewska, D. (1993). Detection of Coxiella burnetii bacteria in urine and semen with dot-ELISA and IFA as diagnostic methods in rapid recognition of Q fever. Serodiag. Immunother. Infect. Dis. 5, 220–223. USNRC. (2007). ‘‘Improving the Nation’s Water Security: Opportunities for Research.’’ National Academies Press, Washington DC, USA. Wacharapluesadee, S., and Hemachudha, T. (2002). Urine samples for rabies RNA detection in the diagnosis of rabies in humans. Clin. Infect. Dis. 34, 874–875. Wang, X. W., Li, J. S., Guo, T. K., Zhen, B., Kong, Q. X., Yi, B., Li, Z., Song, N., Jin, M., and Xiao, W. J. (2005). Concentration and detection of SARS coronavirus in sewage from Xiao Tang Shan hospital and the 309th hospital. J. Virol. Methods 128, 156–161. Ward, R. L., Knowlton, D. R., and Pierce, M. J. (1984). Efficiency of human rotavirus propagation in cell-culture. J. Clin. Microbiol. 19, 748–753. WHO (2003). ‘‘Guidelines for Environmental Surveillance of Poliovirus Circulation.’’ World Health Organization, Geneva, Switzerland. Yolken, R. H., Li, S., Perman, J., and Viscidi, R. (1991). Persistent diarrhea and fecal shedding of retroviral nucleic acids in children infected with human immunodeficiency virus. J. Infect. Dis. 164, 61–66.
INDEX A Acid adaptation in food, 71, 73 pathogens culture, 69–70 Acid resistance acidic gastricbarrier, 71 acid tolerance response (ATR), 124 glutamate decarboxylase (GAD) system acid tolerance model, 125 decarboxylases and operons, 124–125 GABA removal, 125–126 H2-receptor antagonist, 71–72 listerial mechanisms arginine and agmatine deiminase systems, 76 cell membrane changes, 78–79 F0F1-ATPase, 76–77 GAD system, 73–75 LisRK two-component regulatory system, 81–82 macromolecular protection and repair, 77–78 sigma B factor, 79–81 and listerial survival in foods, 70–71 pH environments, 124 simulated gastric fluid, 73 in vivo and in vitro environments, 72 Acid tolerance response (ATR), 69–70 Agmatine deiminase (ADI) systems, 76 Agrobacterium tumefaciens, 158–159 agu genes, 76 Antimicrobial resistance, 127 ATP-binding cassette (ABC) type I, 144, 147, 151 Atx1/CopZ proteins, 235–236 Autotransporter–2 (AT–2) systems, 165–166 B Bacillus anthracis, 254 Bacillus subtilis sB activity regulation, 118–120 copper homeostasis CopZ and Sco1copper chaperones, 236
CsoR-family copper sensors, 234 P1B-type ATPase CopA system, 230 principles of, 221–222 trafficking mechanism, 223 copper-requiring proteins, 221 sigma factor, 118 Bacterial biological control agents, rhizospheres biocontrol mechanism, 202 metabolic behavior, 203–204 metabolic energy status, 202–203 plant influences, microbial metabolism antibiotic production, 210–211 bacterial chemotaxis, 208 bacterial colony, 206–207 colonization, 207–208 fatty acids, 209–210 gene expression, 210 plant root exudates, 207 resource competition, 209 root factors and metabolic process, 206 siderophore production, 211–212 rhizobacteria, 201–202 soil edaphic factors and indigenous microbes, 204–206 abiotic soil factors, 204–205 biological components, 205–206 nutrients, 204 physical and chemical factors, 205 quorum-sensing regulatory systems, 206 Bacterial capsule functions, 2–3 Bacterial copper homeostatic systems Bacillus subtilis copper-requiring proteins, 221 CopZ and Sco1copper chaperones, 236 CsoR-family copper sensors, 234 P1B-type ATPase CopA system, 230 principles of, 221–222 trafficking mechanism, 223 Enterococcus hirae CopY-family copper sensors, 234 CopZ/Atx1copper chaperones, 235–236
271
272
Index
Bacterial copper homeostatic systems (cont.) P1B-type ATPases, 225 trafficking mechanism, 223 Escherichia coli copper acquisition, 225 copper-dependent proteins, 221 copper-resistant strains, 239 cue system, 228–230 cus system, 230–233 MerR-family copper-sensors, 233 P1B-type ATPases, 224–225 plasmid-borne pco system, 227–228 principles of, 221–223 Salmonella typhimurium copper and pathogenicity, 237–238 extracytoplasmic copper and, 237 MerR-family copper-sensors, 233 MerR-type copper-responsive regulators, 230–231 Synechocystis PCC 6803 copper-chaperones, 235 FutA2, 226 P1B-type ATPases, 225–226 P1B-type ATPases CopA system, 230 trafficking mechanism, 223 BetL transporters, 122–123 bilE operon, 128 Biodegradation, PAHs abiotic and biotic factors, 34–35 bacterial degradation, 35–36 carbon and energy sources, 35 fungal degradation, 36–37 marker genes, 45–50 microbial communities, 38–45 prokaryotic and eukaryotic algae, 37–38 Bioremediation, PAHs biosurfactants, 51–52 landfarming approach, 50–51 PAH oxygen levels, 52 phenanthrene and pyrene ring degradation, 52–53 strategies, 50 Bordetella pertussis, 158, 168–169 Branched-chain fatty acid (BCFA), 79 Brucella abortus, 256 bsh (bile salt hydrolase) gene, 128 C cAMP receptor protein (CRP), 96 Capsular polysaccharides, Escherichia coli capsule expression regulation
K30 capsule and colanic acid (slime) in, 16–18 K5 polysaccharide gene cluster, 18–20 Group 1 capsules biosynthetic locus for, 4 glycosyltransferase enzyme, 5 wza, wzb, and wzc translocation genes, 5–6 Group 2 capsules ABC–2 transporters, 13 genetics and evolution, 8–10 kfi gene products, 11 K5 polysaccharide synthesis and export, 10–11 KpsC and KpsS proteins, 12 KpsE and KpsD mutants, 13–14 KpsM and KpsT, 12–13 RhsA protein, 19 synthesis and export coupling in, 14–16 Group 3 and 4 capsules, 6–7 H-NS and BipA regulatory protein, 19 IHF regulatory protein, 18 JUMPStart promoter role, 18 K1 capsule, 3 K5 capsule, 9, 11, 14 polysaccharide engineering, 20–21 Caulobacter crescentus, 104 Chaperonins, 78 cheA mutant, 208 Chloroplast envelope protein translocase (CEPT) Tic proteins, 177–178 Toc proteins, 176–179 Chromatin immunoprecipitation, ChIP-chip immunoprecipitated DNA analysis, 102 nucleoid-associated proteins, 105–106 RNA polymerase-omics, 106 sequence specific transcription factors, 102–105 clpP gene, 127 Colanic acid expression, E. coli K–12 strains, 16–18 Copper, bacteria biocide, 239–240 copper homeostasis copper acquisition, 225–227 copper-chaperones, 235–236 detoxification, 227–233 P1B-type ATPases, 224–225 principle, 221–222 sensors, 233–235 trafficking mechanism, 223
273
Index
copper requiring proteins, 220–221 pathogenicity copper-exporting P1B-type ATPase gene, 238–239 copper levels, 236–237 oxidative burst, 237–238 properties distribution, 219 oxidation states, 220 Copper-chaperones Atx1/CopZ proteins, 235–236 Sco proteins, 236 CopY-family copper sensors, 234 Coxsackievirus B5, 264 Creosote, 33 Cryotolerance, 126 CsoR-family copper sensors, 234–235 CusF protein, 232–233 Cytochrome oxidase biogenesis (Oxal) family, 149 D 2,4-Diacetylphloroglucinol (DAPG) antibiotics, 211 dnaK gene, 78 DNA-stable isotope probing (DNA-SIP), 44 E Edwardsiella tarda, 160 Enterobacter cloacae fatty-acids, 210 mutant strains, 207–208 Enterococcus hirae, copper homeostasis CopY-family copper sensors, 234 CopZ/Atx1copper chaperones, 235–236 P1B-type ATPases, 225 trafficking mechanism, 223 Escherichia coli capsular polysaccharides, 3 capsule expression regulation, 16–20 ChIP-chip experimental protocols for, 106–109 copper homeostasis copper acquisition, 225 copper-dependent proteins, 221 cue system, 228–230 cus system, 230–233 MerR-family copper-sensors, 233 P1B-type ATPases, 224–225 plasmid-borne pco system, 227–228 principles of, 221–223
copper-resistant strains, 239 dps promoter, 99–100 general secretory pathway (SP) systems, 144, 148 Group 1 capsules, 4–6 Group 2 capsules biosynthesis of, 10–12 capsule export pathway, 12–13 genetics and evolution, 8–10 Group 3 and 4 capsules, 6–7 lac and melR promoters, 97–98 nucleoid-associated proteins, 99 RNA polymerase activity, 94 twin arginine targeting translocase (Tat), 160–162 YaeT of, 171 E. tarda virulent protein (EVP) gene, 160 Expression of extracellular polysaccharide (EPS), 2 F F0F1-ATPase, 76–77 Fimbrial usher porins (FUP), OMP translocases, 164–165 Fis nucleoid-associated protein, 99–101, 105 Flavivirus, 256 FliJ flagellar export protein, 156 Fumarate and nitrate reductase (FNR), 96 Fungal degradation, PAH ligninolytic fungi, 37 nonligninolytic fungi, 36–37 G GAD enzyme, 74–75 g-aminobutyrate (GABA) neutral compound, 73–74 Gbu transporters, 122–123 Gene encoding GAD enzyme, 74–75 genomic analysis, 76 homologous 3-enzyme pathway, 76 sB regulon, 80 General secretory translocases (Sec) systems, 152–153, 167, 176 Global transcription factors class I activator dependent promoters, 97–98 class II activator dependent promoters, 98 class III activator dependent promoters, 98–99 CRP and FNR, 96 nucleoid-associated proteins, 99
274
Index
Glutamate decarboxylase (GAD) system acid tolerance response (ATR), 74 genome analysis, 74–75 pH homeostasis, 73 in specific food models, 75 Glutamate/g-aminobutyrate (GABA) antiporters, 124–126 Glycosyltransferase enzymes, E. coli, 11 Gram-negative bacteria OMP translocases autotransporter–1 (AT–1) systems, 165 autotransporter–2 (AT–2) systems, 165–166 FUP systems, 164–165 MTB, 162–164 OMP insertion porins (OMPIP), 170–172 two-partner secretion (TPS) systems, 167–170 protein secretory pathways (PSP) in, 145–146 putative type VI symbiosis/virulence secretory systems, 159–160 twin arginine translocation (Tat) systems, 160–162 type II GSP (Sec) systems in, 152–153 type III flagellar and pathogenicityrelated systems, 154–157 type I (ABC–MFP–OMF-type) protein exporters, 151–152 type IV conjugation-and virulence-related (IVSP) systems, 157–159 Gram positive intracellular pathogen, 68 H Helicobacter pylori, 158–159 H-NS nucleoid-associated protein, 100–101, 105 Human pathogens monitoring, sewage systems released duration and concentration in infection, 256 infectivity assays, 260 molecular detection, 256, 258 super-excretors and spreader, 261 secretion, 254–256 I IHF nucleoid-associated protein, 100–101, 105 Inner chloroplast membrane translocase (TIC), 176–177
Inner membrane secretory systems, bacteria putative type VI symbiosis/virulence secretory systems E. tarda virulent protein (EVP) gene, 160 V. cholerae Vas system, 159–160 twin arginine translocation (Tat) systems homologues proteins, 162 redox enzymes translocation, 161 type II GSP (Sec) systems, 152–153 type III flagellar and pathogenicityrelated systems flagella and injectosomes, 157 FliJ flagellar export protein, 156 needle complex, 156–157 schematic structure, 154 Yersinia spp., 155 type I (ABC–MFP–OMF-type) protein exporters, 151–152 type IV conjugation-and virulence-related (IVSP) systems characteristics, 159 VirB systems, 157–158 Integration host factor (IHF), 18–19 K Klebsiella species, 162–163 L Legionella pneumophila, 159 Linoleic acid, 209 LisRK two-component regulatory system, 81–82 Listeria monocytogenes acid resistance, 71–73 acidic gastricbarrier, 71 H2-receptor antagonist, 71–72 listerial mechanism, 73–82 listerial survival in foods, 70–71 simulated gastric fluid, 73 in vivo and in vitro environments, 72 acid tolerance response (ATR), 69–70 adaptable pathogen, 116 listeriosis, 68–69 sigma factors bacillus subtilis, 118 gene encoding, 116–117 growth rate, 128–129 M Main terminal branch (MTB) systems, OMP translocases
275
Index
PulD secretin, 162–163 trans-periplasmic complex, 164 Marburg virus, 256 Mechanosensitive channels (MscL), 149 MerR-family copper-sensors, 233 Methanobactin, 226–227 Methylococcus casulatus (Bath), 226–227 Methylosinus trichosporium OB3b, 226–227 Microbial communities, PAH bioremediation acclimation period, 51 natural attenuation, 50 degradation DNA-stable isotope probing (DNA-SIP), 44–45 fingerprint techniques, 38–39 Mitochondrial protein translocases ( MPT) Mia40p and Erv1p, 174–175 Tim proteins, 173–176 Tom channel complex, 172–173 N ndo genes, 48 Neisseria meningitidis, 7, 11–14, 170 Nucleoid-associated proteins Fis protein, 99–101 IHF and H-NS proteins, 101 ilvGMEDA operon, 101 promoter opening, 100 O O-antigen capsules, 6 OMP insertion porins (OMPIP) Omp85 structural gene, 170 YaeT of E. coli, 170–171 OMP translocases, gram-negative bacteria Autotransporter–1 (AT–1) systems, 165 Autotransporter–2 (AT–2) systems, 165–166 FUP systems, 164–165 MTB, 162–164 OMP insertion porins (OMPIP), 170–172 two-partner secretion (TPS) systems, 167–170 Outer chloroplast membrane translocase (TOC), 176–179 Outer membrane accessory (OMA) protein, 5, 13 Outer membrane factors (OMFs), 144, 151–152
P Parainfluenza virus, 256 Pathogen monitoring, sewage systems detection probability, 266–268 human pathogens, bodily fluids released duration and concentration, 256, 258–261 secretion, 254–256 microbial replication and infection, 253–254 pathogens concentration, 261–262 detection, 262–263 survival, 263–264 poliovirus monitoring sensitivity assessment, 264 vaccination programs, 264–265 vaccine and virulent strains, 265–266 wastewater, 252–253 pfkA mutant, Enterobacter cloacae, 208 Phanerochaete chrysosporium, 37 phn-Like genes, 48 Piezotolerance, 126–127 Poliovirus monitoring, sewage systems sensitivity assessment, 264 vaccination programs, 264–265 vaccine and virulent strains, 265–266 Polycyclic aromatic hydrocarbons (PAHs) bioremediation biosurfactants, 51–52 landfarming approach, 50–51 PAH oxygen levels, 52 phenanthrene and pyrene ring degradation, 52–53 strategies of, 50 chemical and physical properties, 28–31 degradation abiotic and biotic factors, 34–35 bacterial degradation, 35–36 carbon and energy sources, 35 fungal degradation, 36–37 marker genes, 45–50 microbial communities, 38–45 prokaryotic and eukaryotic algae, 37–38 environmental contamination, 33–34 sources, 33 toxicity exposure, 28, 32 minimal risk levels, 32 Polypeptide transport-associated (POTRA) domains, OMPIP, 170–172 prfA gene, 130
276
Index
Promoters, E. coli, 95 Protein-import-related anion channel (PIRAC), 178 Protein secretory pathways (PSP), 144–146 Protein translocases ATP-binding cassette (ABC) type I, 144, 147 eukaryotic organelles CEPT complexes, 176–179 MPT complexes, 172–176 general secretory pathway (SP) systems, 144, 148 in Gram-negative bacteria, 145–146 holin proteins, 149–150 protein export systems comparison, 178–180 Proton motive force (PMF), 77 Pseudomonas fluorescens antibiotic production, 211–212 bacterial chemotaxis, 208 soil factors, 205 vs. Pythium ultimum, 211 pva gene, 127 Pyochelin, 212 Pyoluteorin antibiotics, 211 Pyrrolnitrin antibiotics, 211 Pythium ultimum spore germination, 209–210 vs. Pseudomonas fluorescens, 211 Q Qualitative microbial risk assessment (QMRA), 252–253 Quorum-sensing regulatory systems, 206 R Rcs phosphorelay system, E. coli, 16–17 Rhizospheres, bacterial biological control agents biocontrol mechanisms, 202 definition, 201 metabolic behavior, 203–204 metabolic energy status, 202–203 plant influences, microbial metabolism antibiotic production, 210–211 bacterial chemotaxis, 208 bacterial colony, 206–207 colonization, 207–208 fatty acids, 209–210 gene expression, 210 plant root exudates, 207 pseudomonas fluorescens, 211
resource competition, 209 root factors and metabolic processes, 206 siderophore production, 211–212 rhizobacteria, 201–202 soil edaphic factors and indigenous microbes, 204–206 abiotic soil factors, 204–205 biological components, 205–206 nutrients, 204 physical and chemical factors, 205 quorum-sensing regulatory systems, 206 Rho protein, 9 RNA polymerase, 119 bacterial multi-subunit of, 94 DNA recognition promoters, 95 s factors role, 94–95 rpoD gene, 116, 118 RpoS factor, 79 S Salmonella species, 69, 71, 81 Salmonella typhimurium, copper homeostasis copper and pathogenicity copper trafficking proteins, 237 P1B-type ATPases, 238 extracytoplasmic copper and, 237 MerR-family copper-sensors, 233 MerR-type copper-responsive regulators, 230–231 SCFA. See Straight chain fatty acid Secretory pathway (SP) systems, bacteria putative type VI symbiosis/virulence secretory systems E. tarda virulent protein (EVP) gene, 160 V. cholerae Vas system, 159–160 Twin arginine translocation (Tat) systems homologues proteins, 162 redox enzymes translocation, 161 type II GSP (Sec) systems, 152–153 type III flagellar and pathogenicityrelated systems flagella and injectosomes, 157 FliJ flagellar export protein, 156 needle complex, 156–157 schematic structure, 154 Yersinia spp., 155 type I (ABC–MFP–OMF-type) protein exporters, 151–152 type IV conjugation-and virulence-related (IVSP) systems
277
Index
characteristics, 159 VirB systems, 157–158 Selenastrum capricornutum, 38 Serine proteases, 78 Serratia marcescens, 166 Sewage system monitoring human pathogens in bodily fluids, 254–258 release duration and concentration, 256, 258–261 wastewater monitoring, 252–253 nonenteric pathogens, 256 pathogen concentration, 261–262 detection, 262–263 survival, 263–264 poliovirus sensitivity assessment, 264 vaccination programs, 264–265 vaccine and virulent strains, 265–266 sigB gene, 79–80 DsigB mutant acid resistance, 124–126 bile resistance, 128 cryotolerance, 126 in metabolism, 129 Sigma B factor, Listeria monocytogenes complex protein–protein interactions operon transcription, 121 RsbT and RsbR factors, 120–121 RsbU and RsbP factors, 119–120 RsbV factor and RsbW factors, 118–119 sB activity regulation, 120–121 sigB operon conservation, 118–119 environmental stresses, 80 gram-positive bacteria, 79 low pH conditions, 80–81 in metabolism, 129–130 sB regulon, 79–80 stress adaptation acid resistance, 124–126 antimicrobial resistance, 127 bile resistance, 128 in cryotolerance, 126 osmoregulation, 122–123 in piezotolerance, 126–127 in virulence early and extracellular infection stages, 131–133 PrfA and intracellular infection stages, 130–131
Signal recognition particle (SRP), 153, 175 Simulated gastric fluid, 73 Soil guideline values (SGVs), 34 Straight chain fatty acid (SCFA), 79 Synechocystis PCC 6803, copper homeostasis copper-chaperones, 235 FutA2, 226 P1B-type ATPases, 225–226 P1B-type ATPases CopA system, 230 trafficking mechanism, 223 Synechocystis protein, 177 T TolC protein, 152 Trametes versicolor, 37 Transcription regulation global transcription factors class I activator dependent promoters, 97–98 class II activator dependent promoters, 98 class III activator dependent promoters, 98–99 CRP and FNR, 96 nucleoid-associated proteins, 99–101 transcription regulators, 96 Translocator in outer membrane (TOM) complex, 171–174 Transporter classification (TC) system, 142–143 Transport protein classification, 142–143 Twin arginine targeting (Tat) translocases system, 147 homologues proteins, 162 redox enzymes translocation, 161 Two-partner secretion (TPS) systems, OMP translocases FhaC protein, 167–168 ShlB protein, 167 transport protein and substrate protein, 166 U Unsaturated fatty acids, 79 V vasA-L (virulence-associated secretion) gene, 159 Vibrio cholerae, 159–160 Virulence, sB factor early and extracellular infection stages
278
Virulence, sB factor (cont.) duodenum and gall bladder survival, 131–132 high osmotic pressure, 132–133 small intestine survival and intestinal epithelium invasion, 133 stomach survival, 131
Index
PrfA and intracellular infection stages, 130–131 Y Yersina pestis, 254 Yersinia enterocolitica, 165
CONTENTS OF PREVIOUS VOLUMES
Volume 40 Microbial Cellulases: Protein Architecture, Molecular Properties, and Biosynthesis Ajay Singh and Kiyoshi Hayashi Factors Inhibiting and Stimulating Bacterial Growth in Milk: An Historical Perspective D. K. O’Toole Challenges in Commercial Biotechnology. Part I. Product, Process, and Market Discovery Alesˇ Prokop Challenges in Commercial Biotechnology. Part II. Product, Process, and Market Development Alesˇ Prokop Effects of Genetically Engineered Microorganisms on Microbial Populations and Processes in Natural Habitats Jack D. Doyle, Guenther Stotzky, Gwendolyn McClung, and Charles W. Hendricks Detection, Isolation, and Stability of Megaplasmid-Encoded Chloroaromatic Herbicide-Degrading Genes within Pseudomonas Species Douglas J. Cork and Amjad Khalil
Improving Productivity of Heterologous Proteins in Recombinant Saccharomyces cerevisiae Fermentations Amit Vasavada Manipulations of Catabolic Genes for the Degradation and Detoxification of Xenobiotics Rup Lal, Sukanya Lal, P. S. Dhanaraj, and D. M. Saxena Aqueous Two-Phase Extraction for Downstream Processing of Enzymes/Proteins K. S. M. S. Raghava Rao, N. K. Rastogi, M. K. Gowthaman, and N. G. Karanth Biotechnological Potentials of Anoxygenic Phototrophic Bacteria. Part I. Production of Single Cell Protein, Vitamins, Ubiquinones, Hormones, and Enzymes and Use in Waste Treatment Ch. Sasikala and Ch. V. Ramana Biotechnological Potentials of Anoxygenic Phototrophic Bacteria. Part II. Biopolyesters, Biopesticide, Biofuel, and Biofertilizer Ch. Sasikala and Ch. V. Ramana Index
Volume 42
Volume 41
The Insecticidal Proteins of Bacillus thuringiensis P. Ananda Kumar, R. P. Sharma, and V. S. Malik
Microbial Oxidation of Unsaturated Fatty Acids Ching T. Hou
Microbiological Production of Lactic Acid John H. Litchfield
Index
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280
Contents of Previous Volumes
Biodegradable Polyesters Ch. Sasikala The Utility of Strains of Morphological Group II Bacillus Samuel Singer
Investigation of the Carbon- and Sulfur-Oxidizing Capabilities of Microorganisms by Active-Site Modeling Herbert L. Holland
Phytase Rudy J. Wodzinski and A. H. J. Ullah
Microbial Synthesis of D-Ribose: Metabolic Deregulation and Fermentation Process P. de Wulf and E. J. Vandamme
Index
Production and Application of Tannin Acyl Hydrolase: State of the Art P. K. Lekha and B. K. Lonsane
Volume 43 Production of Acetic Acid by Clostridium thermoaceticum Munir Cheryan, Sarad Parekh, Minish Shah, and Kusuma Witjitra Contact Lenses, Disinfectants, and Acanthamoeba Keratitis Donald G. Ahearn and Manal M. Gabriel Marine Microorganisms as a Source of New Natural Products V. S. Bernan, M. Greenstein, and W. M. Maiese Stereoselective Biotransformations in Synthesis of Some Pharmaceutical Intermediates Ramesh N. Patel Microbial Xylanolytic Enzyme System: Properties and Applications Pratima Bajpai Oleaginous Microorganisms: An Assessment of the Potential Jacek Leman Index
Volume 44 Biologically Active Fungal Metabolites Cedric Pearce Old and New Synthetic Capacities of Baker’s Yeast P. D’Arrigo, G. Pedrocchi-Fantoni, and S. Servi
Ethanol Production from Agricultural Biomass Substrates Rodney J. Bothast and Badal C. Saha Thermal Processing of Foods, A Retrospective, Part I: Uncertainties in Thermal Processing and Statistical Analysis M. N. Ramesh, S. G. Prapulla, M. A. Kumar, and M. Mahadevaiah Thermal Processing of Foods, A Retrospective, Part II: On-Line Methods for Ensuring Commercial Sterility M. N. Ramesh, M. A. Kumar, S. G. Prapulla, and M. Mahadevaiah Index
Volume 45 One Gene to Whole Pathway: The Role of Norsolorinic Acid in Aflatoxin Research J. W. Bennett, P.-K. Chang, and D. Bhatnagar Formation of Flavor Compounds in Cheese P. F. Fox and J. M. Wallace The Role of Microorganisms in Soy Sauce Production Desmond K. O’Toole Gene Transfer Among Bacteria in Natural Environments Xiaoming Yin and G. Stotzky
Contents of Previous Volumes
Breathing Manganese and Iron: Solid-State Respiration Kenneth H. Nealson and Brenda Little
Microbial Production of Oligosaccharides: A Review S. G. Prapulla, V. Subhaprada, and N. G. Karanth
Enzymatic Deinking Pratima Bajpai
Index
Microbial Production of Docosahexaenoic Acid (DHA, C22:6) Ajay Singh and Owen P. Word Index
Volume 46 Cumulative Subject Index
Volume 47 Seeing Red: The Story of Prodigiosin J. W. Bennett and Ronald Bentley Microbial/Enzymatic Synthesis of Chiral Drug Intermediates Ramesh N. Patel Recent Developments in the Molecular Genetics of the Erythromycin-Producing Organism Saccharopolyspora erythraea Thomas J. Vanden Boom Bioactive Products from Streptomyces Vladisalv Behal Advances in Phytase Research Edward J. Mullaney, Catherine B. Daly, and Abdul H. J. Ullah Biotransformation of Unsaturated Fatty Acids of industrial Products Ching T. Hou Ethanol and Thermotolerance in the Bioconversion of Xylose by Yeasts Thomas W. Jeffries and Yong-Su Jin Microbial Degradation of the Pesticide Lindane (g-Hexachlorocyclohexane) Brajesh Kumar Singh, Ramesh Chander Kuhad, Ajay Singh, K. K. Tripathi, and P. K. Ghosh
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Volume 48 Biodegredation of Nitro-Substituted Explosives by White-Rot Fungi: A Mechanistic Approach Benoit Van Aken and Spiros N. Agathos Microbial Degredation of Pollutants in Pulp Mill Effluents Pratima Bajpai Bioremediation Technologies for Metal-Containing Wastewaters Using Metabolically Active Microorganisms Thomas Pumpel and Kishorel M. Paknikar The Role of Microorganisms in Ecological Risk Assessment of Hydrophobic Organic Contaminants in Soils C. J. A. MacLeod, A. W. J. Morriss, and K. T. Semple The Development of Fungi: A New Concept Introduced By Anton de Bary Gerhart Drews Bartolomeo Gosio, 1863–1944: An Appreciation Ronald Bentley Index
Volume 49 Biodegredation of Explosives Susan J. Rosser, Amrik Basran, Emmal R. Travis, Christopher E. French, and Neil C. Bruce Biodiversity of Acidophilic Prokaryotes Kevin B. Hallberg and D. Barrie Johnson
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Contents of Previous Volumes
Laboratory Birproduction of Paralytic Shellfish Toxins in Dinoflagellates Dennis P. H. Hsieh, Dazhi Wang, and Garry H. Chang Metal Toxicity in Yeasts and the Role of Oxidative Stress S. V. Avery Foodbourne Microbial Pathogens and the Food Research Institute M. Ellin Doyle and Michael W. Pariza Alexander Flemin and the Discovery of Penicillin J. W. Bennett and King-Thom Chung Index
Volume 50 Paleobiology of the Archean Sherry L. Cady A Comparative Genomics Approach for Studying Ancestral Proteins and Evolution Ping Liang and Monica Riley Chromosome Packaging by Archaeal Histones Kathleen Sandman and John N. Reeve DNA Recombination and Repair in the Archaea Erica M. Seitz, Cynthia A. Haseltine, and Stephen C. Kowalczykowski Basal and Regulated Transcription in Archaea Jo¨rg Soppa Protein Folding and Molecular Chaperones in Archaea Michel R. Leroux Archaeal Proteasomes: Proteolytic Nanocompartments of the Cell Julie A. Maupin-Furlow, Steven J. Kaczowka, Mark S. Ou, and Heather L. Wilson Archaeal Catabolite Repression: A Gene Regulatory Paradigm Elisabetta Bini and Paul Blum Index
Volume 51 The Biochemistry and Molecular Biology of Lipid Accumulation in Oleaginous Microorganisms Colin Ratledge and James P. Wynn Bioethanol Technology: Developments and Perspectives Owen P. Ward and Ajay Singh Progress of Aspergillus oryzae Genomics Masayuki Machida Transmission Genetics of Microbotryum violaceum (Ustilago violacea): A Case History E. D. Garber and M. Ruddat Molecular Biology of the Koji Molds Katsuhiko Kitamoto Noninvasive Methods for the Investigation of Organisms at Low Oxygen Levels David Lloyd The Development of the Penicillin Production Process in Delft, The Netherlands, During World War II Under Nazi Occupation Marlene Burns and Piet W. M. van Dijck Genomics for Applied Microbiology William C. Nierman and Karen E. Nelson Index
Volume 52 Soil-Based Gene Discovery: A New Technology to Accelerate and Broaden Biocatalytic Applications Kevin A. Gray, Toby H. Richardson, Dan E. Robertson, Paul E. Swanson, and Mani V. Subramanian The Potential of Site-Specific Recombinases as Novel Reporters in Whole-Cell Biosensors of Pollution Paul Hinde, Jane Meadows, Jon Saunders, and Clive Edwards
Contents of Previous Volumes
Microbial Phosphate Removal and Polyphosphate Production from Wastewaters John W. McGrath and John P. Quinn Biosurfactants: Evolution and Diversity in Bacteria Raina M. Maier Comparative Biology of Mesophilic and Thermophilic Nitrile Hydratases Don A. Cowan, Rory A. Cameron, and Tsepo L. Tsekoa From Enzyme Adaptation to Gene Regulation William C. Summers Acid Resistance in Escherichia coli Hope T. Richard and John W. Foster Iron Chelation in Chemotherapy Eugene D. Weinberg Angular Leaf Spot: A Disease Caused by the Fungus Phaeoisariopsis griseola (Sacc.) Ferraris on Phaseolus vulgaris L. Sebastian Stenglein, L. Daniel Ploper, Oscar Vizgarra, and Pedro Balatti The Fungal Genetics Stock Center: From Molds to Molecules Kevin McCluskey Adaptation by Phase Variation in Pathogenic Bacteria Laurence Salau¨n, Lori A. S. Snyder, and Nigel J. Saunders What Is an Antibiotic? Revisited Ronald Bentley and J. W. Bennett An Alternative View of the Early History of Microbiology Milton Wainwright The Delft School of Microbiology, from the Nineteenth to the Twenty-first Century Lesley A. Robertson
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Anaerobic Dehalogenation of Organohalide Contaminants in the Marine Environment Max M. Ha¨ggblom, Young-Boem Ahn, Donna E. Fennell, Lee J. Kerkhof, and Sung-Keun Rhee Biotechnological Application of Metal-Reducing Microorganisms Jonathan R. Lloyd, Derek R. Lovley, and Lynne E. Macaskie Determinants of Freeze Tolerance in Microorganisms, Physiological Importance, and Biotechnological Applications An Tanghe, Patrick Van Dijck, and Johan M. Thevelein Fungal Osmotolerance P. Hooley, D. A. Fincham, M. P. Whitehead, and N. J. W. Clipson Mycotoxin Research in South Africa M. F. Dutton Electrophoretic Karyotype Analysis in Fungi J. Beadle, M. Wright, L. McNeely, and J. W. Bennett Tissue Infection and Site-Specific Gene Expression in Candida albicans Chantal Fradin and Bernard Hube LuxS and Autoinducer-2: Their Contribution to Quorum Sensing and Metabolism in Bacteria Klaus Winzer, Kim R. Hardie, and Paul Williams Microbiological Contributions to the Search of Extraterrestrial Life Brendlyn D. Faison Index
Volume 54
Volume 53
Metarhizium spp.: Cosmopolitan InsectPathogenic Fungi – Mycological Aspects Donald W. Roberts and Raymond J. St. Leger
Biodegradation of Organic Pollutants in the Rhizosphere Liz J. Shaw and Richard G. Burns
Molecular Biology of the Burkholderia cepacia Complex Jimmy S. H. Tsang
Index
284
Contents of Previous Volumes
Non-Culturable Bacteria in Complex Commensal Populations William G. Wade l Red-Mediated Genetic Manipulation of Antibiotic-Producing Streptomyces Bertolt Gust, Govind Chandra, Dagmara Jakimowicz, Tian Yuqing, Celia J. Bruton, and Keith F. Chater Colicins and Microcins: The Next Generation Antimicrobials Osnat Gillor, Benjamin C. Kirkup, and Margaret A. Riley Mannose-Binding Quinone Glycoside, MBQ: Potential Utility and Action Mechanism Yasuhiro Igarashi and Toshikazu Oki
J. D. Cooley, W. C. Wong, C. A. Jumper, and D. C. Straus Fungal Contamination as a Major Contributor to Sick Building Syndrome De-Wei LI and Chin S. Yang Indoor Moulds and Their Associations with Air Distribution Systems Donald G. Ahearn, Daniel L. Price, Robert Simmons, Judith Noble-Wang, and Sidney A. Crow, Jr. Microbial Cell Wall Agents and Sick Building Syndrome Ragnar Rylander The Role of Stachybotrys in the Phenomenon Known as Sick Building Syndrome Eeva-Liisa Hintikka
Protozoan Grazing of Freshwater Biofilms Jacqueline Dawn Parry
Moisture-Problem Buildings with Molds Causing Work-Related Diseases Kari Reijula
Metals in Yeast Fermentation Processes Graeme M. Walker
Possible Role of Fungal Hemolysins in Sick Building Syndrome Stephen J. Vesper and Mary Jo Vesper
Interactions between Lactobacilli and Antibiotic-Associated Diarrhea Paul Naaber and Marika Mikelsaar Bacterial Diversity in the Human Gut Sandra MacFarlane and George T. MacFarlane Interpreting the Host-Pathogen Dialogue Through Microarrays Brian K. Coombes, Philip R. Hardwidge, and B. Brett Finlay The Inactivation of Microbes by Sunlight: Solar Disinfection as a Water Treatment Process Robert H. Reed Index
Volume 55 Fungi and the Indoor Environment: Their Impact on Human Health
The Roles of Penicillium and Aspergillus in Sick Building Syndrome (SBS) Christopher J. Schwab and David C. Straus Pulmonary Effects of Stachybotrys chartarum in Animal Studies Iwona Yike and Dorr G. Dearborn Toxic Mold Syndrome Michael B. Levy and Jordan N. Fink Fungal Hypersensitivity: Pathophysiology, Diagnosis, Therapy Vincent A. Marinkovich Indoor Molds and Asthma in Adults Maritta S. Jaakkola and Jouni J. K. Jaakkola Role of Molds and Mycotoxins in Being Sick in Buildings: Neurobehavioral and Pulmonary Impairment Kaye H. Kilburn
Contents of Previous Volumes
The Diagnosis of Cognitive Impairment Associated with Exposure to Mold Wayne A. Gordon and Joshua B. Cantor Mold and Mycotoxins: Effects on the Neurological and Immune Systems in Humans Andrew W. Campbell, Jack D. Thrasher, Michael R. Gray, and Aristo Vojdani Identification, Remediation, and Monitoring Processes Used in a Mold-Contaminated High School S. C. Wilson, W. H. Holder, K. V. Easterwood, G. D. Hubbard, R. F. Johnson, J. D. Cooley, and D. C. Straus The Microbial Status and Remediation of Contents in Mold-Contaminated Structures Stephen C. Wilson and Robert C. Layton Specific Detection of Fungi Associated With SBS When Using Quantitative Polymerase Chain Reaction Patricia Cruz and Linda D. Stetzenbach Index
Volume 56 Potential and Opportunities for Use of Recombinant Lactic Acid Bacteria in Human Health Sean Hanniffy, Ursula Wiedermann, Andreas Repa, Annick Mercenier, Catherine Daniel, Jean Fioramonti, Helena Tlaskolova, Hana Kozakova, Hans Israelsen, Sren Madsen, Astrid Vrang, Pascal Hols, Jean Delcour, Peter Bron, Michiel Kleerebezem, and Jerry Wells Novel Aspects of Signaling in Streptomyces Development Gilles P. van Wezel and Erik Vijgenboom Polysaccharide Breakdown by Anaerobic Microorganisms Inhabiting the Mammalian Gut Harry J. Flint Lincosamides: Chemical Structure, Biosynthesis, Mechanism of Action, Resistance, and Applications
285
Jaroslav Spı´zˇek, Jitka Novotna´, and Toma´sˇ Rˇezanka Ribosome Engineering and Secondary Metabolite Production Kozo Ochi, Susumu Okamoto, Yuzuru Tozawa, Takashi Inaoka, Takeshi Hosaka, Jun Xu, and Kazuhiko Kurosawa Developments in Microbial Methods for the Treatment of Dye Effluents R. C. Kuhad, N. Sood, K. K. Tripathi, A. Singh, and O. P. Ward Extracellular Glycosyl Hydrolases from Clostridia Wolfgang H. Schwarz, Vladimir V. Zverlov, and Hubert Bahl Kernel Knowledge: Smut of Corn Marı´a D. Garcı´a-Pedrajas and Scott E. Gold Bacterial ACC Deaminase and the Alleviation of Plant Stress Bernard R. Glick Uses of Trichoderma spp. to Alleviate or Remediate Soil and Water Pollution G. E. Harman, M. Lorito, and J. M. Lynch Bacteriophage Defense Systems and Strategies for Lactic Acid Bacteria Joseph M. Sturino and Todd R. Klaenhammer Current Issues in Genetic Toxicology Testing for Microbiologists Kristien Mortelmans and Doppalapudi S. Rupa Index
Volume 57 Microbial Transformations of Mercury: Potentials, Challenges, and Achievements in Controlling Mercury Toxicity in the Environment Tamar Barkay and Irene Wagner-Do¨bler
286
Contents of Previous Volumes
Interactions Between Nematodes and Microorganisms: Bridging Ecological and Molecular Approaches Keith G. Davies Biofilm Development in Bacteria Katharine Kierek-Pearson and Ece Karatan Microbial Biogeochemistry of Uranium Mill Tailings Edward R. Landa Yeast Modulation of Wine Flavor Jan H. Swiegers and Isak S. Pretorius Moving Toward a Systems Biology Approach to the Study of Fungal Pathogenesis in the Rice Blast Fungus Magnaporthe grisea Claire Veneault-Fourrey and Nicholas J. Talbot The Biotrophic Stages of Oomycete–Plant Interactions Laura J. Grenville-Briggs and Pieter van West Contribution of Nanosized Bacteria to the Total Biomass and Activity of a Soil Microbial Community Nicolai S. Panikov Index
Volume 58 Physiology and Biotechnology of Aspergillus O. P. Ward, W. M. Qin, J. Dhanjoon, J. Ye, and A. Singh Conjugative Gene Transfer in the Gastrointestinal Environment Tine Rask Licht and Andrea Wilcks Force Measurements Between a Bacterium and Another Surface In Situ Ruchirej Yongsunthon and Steven K. Lower
Richard ffrench-Constant and Nicholas Waterfield Engineering Antibodies for Biosensor Technologies Sarah Goodchild, Tracey Love, Neal Hopkins, and Carl Mayers Molecular Characterization of Ochratoxin A Biosynthesis and Producing Fungi J. O’Callaghan and A. D. W. Dobson Index
Volume 59 Biodegradation by Members of the Genus Rhodococcus: Biochemistry, Physiology, and Genetic Adaptation Michael J. Larkin, Leonid A. Kulakov, and Christopher C. R. Allen Genomes as Resources for Biocatalysis Jon D. Stewart Process and Catalyst Design Objectives for Specific Redox Biocatalysis Daniel Meyer, Bruno Bu¨hler, and Andreas Schmid The Biosynthesis of Polyketide Metabolites by Dinoflagellates Kathleen S. Rein and Richard V. Snyder Biological Halogenation has Moved far Beyond Haloperoxidases Karl-Heinz van Pe´e, Changjiang Dong, Silvana Flecks, Jim Naismith, Eugenio P. Patallo, and Tobias Wage Phage for Rapid Detection and Control of Bacterial Pathogens in Food Catherine E. D. Rees and Christine E. R. Dodd Gastrointestinal Microflora: Probiotics S. Kolida, D. M. Saulnier, and G. R. Gibson
Actinomycetes and Lignin Degradation Ralph Kirby
The Role of Helen Purdy Beale in the Early Development of Plant Serology and Virology Karen-Beth G. Scholthof and Paul D. Peterson
An ABC Guide to the Bacterial Toxin Complexes
Index
Contents of Previous Volumes
Volume 60 Microbial Biocatalytic Processes and Their Development John M. Woodley Occurrence and Biocatalytic Potential of Carbohydrate Oxidases Erik W. van Hellemond, Nicole G. H. Leferink, Dominic P. H. M. Heuts, Marco W. Fraaije, and Willem J. H. van Berkel Microbial Interactions with Humic Substances J. Ian Van Trump, Yvonne Sun, and John D. Coates Significance of Microbial Interactions in the Mycorrhizosphere Gary D. Bending, Thomas J. Aspray, and John M. Whipps Escherich and Escherichia Herbert C. Friedmann Index
Volume 61 Unusual Two-Component Signal Transduction Pathways in the Actinobacteria Matthew I. Hutchings Acyl-HSL Signal Decay: Intrinsic to Bacterial Cell–Cell Communications Ya-Juan Wang, Jean Jing Huang, and Jared Renton Leadbetter Microbial Exoenzyme Production in Food Peggy G. Braun Biogenetic Diversity of Cyanobacterial Metabolites Ryan M. Van Wagoner, Allison K. Drummond, and Jeffrey L. C. Wright Pathways to Discovering New Microbial Metabolism for Functional Genomics and Biotechnology Lawrence P. Wackett
287
Biocatalysis by Dehalogenating Enzymes Dick B. Janssen Lipases from Extremophiles and Potential for Industrial Applications Moh’d Salameh and Juergen Wiegel In Situ Bioremediation Kirsten S. Jrgensen Bacterial Cycling of Methyl Halides Hendrik Scha¨fer, Laurence G. Miller, Ronald S. Oremland, and J. Colin Murrell Index
Volume 62 Anaerobic Biodegradation of Methyl tert-Butyl Ether (MTBE) and Related Fuel Oxygenates Max M. Ha¨ggblom, Laura K. G. Youngster, Piyapawn Somsamak, and Hans H. Richnow Controlled Biomineralization by and Applications of Magnetotactic Bacteria Dennis A. Bazylinski and Sabrina Schu¨bbe The Distribution and Diversity of Euryarchaeota in Termite Guts Kevin J. Purdy Understanding Microbially Active Biogeochemical Environments Deirdre Gleeson, Frank McDermott, and Nicholas Clipson The Scale-Up of Microbial Batch and Fed-Batch Fermentation Processes Christopher J. Hewitt and Alvin W. Neinow Production of Recombinant Proteins in Bacillus subtilis Wolfgang Schumann
288
Contents of Previous Volumes
Quorum Sensing: Fact, Fiction, and Everything in Between Yevgeniy Turovskiy, Dimitri Kashtanov, Boris Paskhover, and Michael L. Chikindas Rhizobacteria and Plant Sulfur Supply Michael A. Kertesz, Emma Fellows, and Achim Schmalenberger
William Gaze, Colette O’Neill, Elizabeth Wellington, and Peter Hawkey Host Defense Peptides in the Oral Cavity Deirdre A. Devine and Celine Cosseau Index
Antibiotics and Resistance Genes: Influencing the Microbial Ecosystem in the Gut Katarzyna A. Kazimierczak and Karen P. Scott
Volume 64
Index
Microbial Endocrinology: Experimental Design Issues in the Study of Interkingdom Signalling in Infectious Disease Primrose P. E. Freestone and Mark Lyte
Volume 63 A Ferment of Fermentations: Reflections on the Production of Commodity Chemicals Using Microorganisms Ronald Bentley and Joan W. Bennett Submerged Culture Fermentation of ‘‘Higher Fungi’’: The Macrofungi Mariana L. Fazenda, Robert Seviour, Brian McNeil, and Linda M. Harvey Bioprocessing Using Novel Cell Culture Systems Sarad Parekh, Venkatesh Srinivasan, and Michael Horn Nanotechnology in the Detection and Control of Microorganisms Pengju G. Luo and Fred J. Stutzenberger Metabolic Aspects of Aerobic Obligate Methanotrophy Yuri A. Trotsenko and John Colin Murrell
Diversity of Microbial Toluene Degradation Pathways R. E. Parales, J. V. Parales, D. A. Pelletier, and J. L. Ditty
Molecular Genetics of Selenate Reduction by Enterobacter cloacae SLD1a-1 Nathan Yee and Donald Y. Kobayashi Metagenomics of Dental Biofilms Peter Mullany, Stephanie Hunter, and Elaine Allan Biosensors for Ligand Detection Alison K. East, Tim H. Mauchline, and Philip S. Poole Islands Shaping Thought in Microbial Ecology Christopher J. van der Gast Human Pathogens and the Phyllosphere John M. Whipps, Paul Hand, David A. C. Pink, and Gary D. Bending
Bacterial Efflux Transport in Biotechnology Tina K. Van Dyk
Microbial Retention on Open Food Contact Surfaces and Implications for Food Contamination Joanna Verran, Paul Airey, Adele Packer, and Kathryn A. Whitehead
Antibiotic Resistance in the Environment, with Particular Reference to MRSA
Index